mirror of
https://github.com/zenorogue/hyperrogue.git
synced 2024-11-27 14:37:16 +00:00
507 lines
15 KiB
C++
507 lines
15 KiB
C++
namespace nilrider {
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ld timestamp::energy_in_squares() { return vel * vel / (2 * gravity); }
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/** convert rotationally symmetric to internal model */
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EX hyperpoint sym_to_used(hyperpoint H) {
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if(nil) nilv::convert_ref(H, nilv::nmSym, nilv::model_used);
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return H;
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}
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void timestamp::draw_unilcycle(const shiftmatrix& V, const colorscheme& cs) {
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const int points = 60 / (1 + reduce_quality);
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const int spoke_each = 5;
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hyperpoint whpoint[points+1];
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transmatrix Ta = cspin(0, 1, -heading_angle);
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transmatrix Tb = cspin(0, 2, -slope);
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hyperpoint base = Ta * Tb * point31(0, 0, whrad);
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for(int a=0; a<points; a++) {
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ld beta = TAU * a / points + circpos;
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whpoint[a] = base + Ta * point3(whrad*sin(beta),0,whrad*cos(beta));
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}
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whpoint[points] = whpoint[0];
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hyperpoint hub[2];
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const ld hublen = whrad / 2;
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for(int a=0; a<2; a++) {
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hub[a] = base + Ta * point3(0, hublen*(a?1:-1), 0);
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}
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for(int a=0; a<points; a+=spoke_each) for(int b=0; b<2; b++) {
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curvepoint(hub[b]);
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for(int b=0; b<=spoke_each; b++)
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curvepoint(whpoint[a+b]);
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curvepoint(hub[b]);
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if(a&1)
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queuecurve(V * rgpushxto0(where), 0xFFFFFFFF, cs.wheel1, PPR::WALL);
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else
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queuecurve(V * rgpushxto0(where), 0xFFFFFFFF, cs.wheel2, PPR::WALL);
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}
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if(1) {
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curvepoint(base + Ta * point3(hublen, 0, whrad+hublen));
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curvepoint(base + Ta * point3(-hublen, -hublen, whrad+hublen));
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curvepoint(base + Ta * point3(-hublen, +hublen, whrad+hublen));
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curvepoint(base + Ta * point3(hublen, 0, whrad+hublen));
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queuecurve(V * rgpushxto0(where), 0xFF, cs.seat, PPR::WALL);
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for(auto& y: {hublen, -hublen}) {
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curvepoint(base + Ta * point3(hublen * .1, -y, 0));
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curvepoint(base + Ta * point3(hublen * -.1, -y, 0));
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curvepoint(base + Ta * point3(hublen * -.1, 0, whrad + hublen / 2));
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curvepoint(base + Ta * point3(hublen * .1, 0, whrad + hublen / 2));
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curvepoint(base + Ta * point3(hublen * .1, -y, 0));
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queuecurve(V * rgpushxto0(where), 0xFF, cs.seatpost, PPR::WALL);
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curvepoint(base + Ta * point3(hublen * -.1, 0, whrad + hublen / 2));
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curvepoint(base + Ta * point3(hublen * .1, 0, whrad + hublen / 2));
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curvepoint(base + Ta * point3(hublen * .1, 0, whrad + hublen));
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curvepoint(base + Ta * point3(hublen * -.1, 0, whrad + hublen));
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curvepoint(base + Ta * point3(hublen * -.1, 0, whrad + hublen / 2));
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queuecurve(V * rgpushxto0(where), 0xFF, cs.seatpost, PPR::WALL);
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}
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}
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}
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bool tick_debug = false;
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bool timestamp::out_of_surface(level *lev) {
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auto xy = lev->get_xy_i(where);
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char ch = lev->mapchar(xy);
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return ch == '!';
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}
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bool timestamp::collect(level *lev) {
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auto xy = on_surface->get_xy_i(where);
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char ch = on_surface->mapchar(xy);
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if(ch == 'r') return false;
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if(ch == '*') {
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for(int i=0; i<isize(lev->triangles); i++) {
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auto& t = lev->triangles[i];
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if(t.which != on_surface) continue;
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if(t.x == xy.first && t.y == xy.second) collected_triangles |= (1<<i);
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}
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}
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int gid = 0;
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for(auto& g: lev->goals) {
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bool gfailed = failed & Flag(gid);
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bool gsuccess = goals & Flag(gid);
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if(gfailed || gsuccess) continue;
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checkerparam cp {this, lev, reversals};
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auto res = g.check(cp);
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if(res == grFailed) {
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failed |= Flag(gid);
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}
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else if(res == grSuccess) {
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goals |= Flag(gid);
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lev->current_score[gid] = timer;
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if(planning_mode || !loaded_or_planned) {
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auto &res = lev->records[planning_mode][gid];
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if(res == 0 || timer < res) {
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res = timer;
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println(hlog, "saved -- success on goal ", gid, " in time ", timer);
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save();
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}
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}
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}
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gid++;
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}
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return true;
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}
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/* convert heading to integral units, to make saved replays consistent */
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constexpr ld h_units = 360 * 60 * 60;
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constexpr ld h_mul = h_units / TAU;
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/* set to flyvel[2] in the case of crash from below */
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constexpr ld CRASHED_FROM_BELOW = -147;
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int heading_to_int(ld a) {
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a = a * h_mul;
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int ai = floor(a + .5);
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ai = gmod(ai, h_units);
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return ai;
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}
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ld int_to_heading(ld a) {
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return a / h_mul;
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}
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void timestamp::be_consistent() {
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heading_angle = int_to_heading(heading_to_int(heading_angle));
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}
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bool timestamp::tick(level *lev, ld time_left) {
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if(flyvel[2] == CRASHED_FROM_BELOW) return false;
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if(on_surface && !collect(lev)) return false;
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const ld eps = slope_eps;
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if(on_surface) {
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hyperpoint wnext = where;
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wnext[0] += cos(heading_angle) * eps;
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wnext[1] += sin(heading_angle) * eps;
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wnext[2] = on_surface->surface(wnext);
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wnext = gpushxto0(where) * wnext;
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slope = atan(wnext[2] / eps);
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if(out_of_surface(lev)) {
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on_surface = nullptr;
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sstime = timer; chg_slope = gfx_slope;
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flyvel = wnext * vel / hypot_d(3, wnext);
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flyvel[3] = 0;
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}
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}
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timer += time_left;
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if(on_surface) {
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auto ovel = vel;
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vel -= sin(slope) * gravity * time_left;
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if(vel < 0) {
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vel = 0;
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if(ovel == 0) return false;
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}
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auto mvel = (vel + ovel) / 2;
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where[0] += cos(heading_angle) * mvel * cos(slope) * time_left;
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where[1] += sin(heading_angle) * mvel * cos(slope) * time_left;
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where[2] = on_surface->surface(where);
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circvel = mvel / whrad;
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}
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else {
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auto owhere = where;
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auto oflyvel = flyvel;
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flyvel = rgpushxto0(where) * flyvel;
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flyvel[2] -= gravity * time_left / 2;
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// todo rewrite geodesic_step to take gravity into account into RK4 correctly
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flyvel *= time_left;
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nisot::geodesic_step(where, flyvel);
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flyvel /= time_left;
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flyvel[2] -= gravity * time_left / 2;
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auto mflyvel = (flyvel + oflyvel) / 2;
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auto new_heading_angle = atan2(mflyvel[1], mflyvel[0]);
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if(timer >= last_tramp + 0.5) heading_angle = new_heading_angle;
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else {
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while(new_heading_angle < heading_angle - M_PI) new_heading_angle += TAU;
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while(new_heading_angle > heading_angle + M_PI) new_heading_angle -= TAU;
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heading_angle = lerp(heading_angle, new_heading_angle, ilerp(timer - time_left, last_tramp + 0.5, timer));
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}
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flyvel = gpushxto0(where) * flyvel;
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mflyvel = gpushxto0(where) * mflyvel;
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slope = atan(mflyvel[2] / hypot_d(2, mflyvel));
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vel = hypot_d(3, flyvel);
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if(check_crashes_rec(lev, owhere, oflyvel, time_left)) return false;
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}
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circpos += circvel * time_left;
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return true;
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}
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bool timestamp::check_crashes(level* lev, hyperpoint owhere, hyperpoint oflyvel, ld time_left) {
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ld oz = lev->surface(owhere);
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ld z = lev->surface(where);
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if(owhere[2] < oz && where[2] >= z) {
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auto xy = lev->get_xy_i(where);
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char ch = lev->mapchar(xy);
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if(ch != '!') { flyvel[2] = CRASHED_FROM_BELOW; return true; }
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}
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if(owhere[2] > oz && where[2] <= z) {
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auto xy = lev->get_xy_i(where);
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char ch = lev->mapchar(xy);
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if(ch == '!') return false;
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string s0 = ""; s0 += ch;
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ld part = binsearch(0, 1, [&] (ld p) {
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hyperpoint h = lerp(owhere, where, p);
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return h[2] < lev->surface(h);
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});
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timer -= time_left * (1 - part);
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where = lerp(owhere, where, part);
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flyvel = lerp(oflyvel, flyvel, part);
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/* tangent vectors */
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hyperpoint dx = gpushxto0(where) * lev->surface_point(rgpushxto0(where) * point31(slope_eps, 0, 0));
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hyperpoint dy = gpushxto0(where) * lev->surface_point(rgpushxto0(where) * point31(0, slope_eps, 0));
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hyperpoint dz = point30(0, 0, slope_eps);
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/* orthonormalize */
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dx = dx / hypot_d(3, dx);
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dy = dy - dot_d(3, dx, dy) * dy;
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dy = dy / hypot_d(3, dy);
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dz = dz - dot_d(3, dx, dz) * dx;
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dz = dz - dot_d(3, dy, dz) * dy;
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dz = dz / hypot_d(3, dz); dz[3] = 0;
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if(ch == 'T') {
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/* reflect off the trampoline */
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flyvel = flyvel - dot_d(3, flyvel, dz) * dz * 2;
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where[2] = lev->surface(where) + 1e-4;
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last_tramp = timer;
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tramp_head = heading_angle;
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}
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else if(ch == 'V') {
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/* convert velocity on velocity converter */
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vel = hypot_d(3, flyvel);
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on_surface = lev;
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}
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else {
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/* waste some energy */
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flyvel = flyvel - dot_d(3, flyvel, dz) * dz;
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vel = hypot_d(3, flyvel);
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on_surface = lev;
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}
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if(part == 1) return false;
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return !tick(lev, time_left * (1 - part));
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}
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return false;
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}
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bool timestamp::check_crashes_rec(level* l, hyperpoint owhere, hyperpoint oflyvel, ld time_left) {
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if(check_crashes(l, owhere, oflyvel, time_left)) return true;
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for(auto s: l->sublevels) if(check_crashes(s, owhere, oflyvel, time_left)) return true;
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return false;
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}
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void timestamp::centerview(level *lev) {
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// static bool once = false; if(once) return; once = true;
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if(vrhr::active()) {
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transmatrix Ta = cspin(0, 1, -heading_angle);
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transmatrix Tb = cspin(0, 2, -slope);
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hyperpoint base = Ta * Tb * point31(0, 0, whrad);
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hyperpoint refpoint = rgpushxto0(where) * rgpushxto0(base) * point31(0, 0, whrad*3);
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centerover = cwt.at; playermoved = false;
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View = cspin(0, 2, heading_angle-90*degree) * cspin(1, 2, -90*degree) * gpushxto0(refpoint);
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return;
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}
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auto w = where;
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w[2] += 0.2 * lev->scale;
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hyperpoint front = rgpushxto0(w) * sym_to_used(hyperpoint(1e-3 * cos(heading_angle), 1e-3*sin(heading_angle), 0, 1));
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hyperpoint up = w; up[2] += 1e-3;
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set_view(w, front, up);
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transmatrix T = View;
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if(last_draw <= sstime) min_gfx_slope = gfx_slope;
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gfx_slope = min_gfx_slope;
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if(on_surface) gfx_slope = binsearch(-90*degree, min(slope, min_gfx_slope), [&] (ld slope) {
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View = T;
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rotate_view(cspin(1, 2, slope));
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for(int i=0; i<8; i++) {
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shift_view(ztangent(whdist * lev->scale / 8.));
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hyperpoint p = inverse(View) * C0;
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ld room = p[2] - on_surface->surface(p);
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if(room < .1 * lev->scale) return true;
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for(hyperpoint h: {point3(0,0,0), point3(.001,0,0), point3(-.001,0,0), point3(0,-0.001,0), point3(0,0.001,0)})
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if(lev->mapchar(p+h) == 'r') return true;
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}
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return false;
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}, 10);
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if(timer < sstime + 1) {
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ld t = timer - sstime;
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gfx_slope = lerp(chg_slope, gfx_slope, t * t * (3 - 2*t));
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}
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last_draw = timer;
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View = T;
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rotate_view(cspin(1, 2, gfx_slope));
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shift_view(ztangent(whdist * lev->scale));
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centerover = cwt.at;
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playermoved = false;
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}
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string format_timer(ld t) {
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return hr::format("%d:%02d.%02d", int(t / 60), int(t) % 60, int(frac(t) * 100));
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}
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void timestamp::draw_instruments(level* l) {
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dynamicval<eGeometry> g(geometry, gEuclid);
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dynamicval<eModel> pm(pmodel, mdDisk);
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dynamicval<bool> ga(vid.always3, false);
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dynamicval<color_t> ou(poly_outline);
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dynamicval<geometryinfo1> gi(ginf[gEuclid].g, giEuclid2);
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initquickqueue();
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check_cgi(); cgi.require_shapes();
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ld rad = 40;
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ld cx = rad * 2;
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ld cy = rad * 2;
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auto sId = shiftless(Id);
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ld pix = 1 / (2 * cgi.hcrossf / cgi.crossf);
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// clinometer
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cx += rad * 1.2;
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for(int i=-90; i<=90; i++)
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curvepoint(atscreenpos(cx+cos(i * degree)*rad, cy-sin(i*degree)*rad, 1) * C0);
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curvepoint(atscreenpos(cx, cy+rad, 1) * C0);
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queuecurve(sId, 0x000000FF, 0xFFFFFF80, PPR::ZERO);
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curvepoint(hpxy(0, 0));
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curvepoint(hpxy(rad, 0));
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/* curvepoint(hpxy(rad/4, 0));
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curvepoint(hpxy(0, rad));
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curvepoint(hpxy(-rad/4, 0));
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curvepoint(hpxy(rad/4, 0)); */
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queuecurve(sId * atscreenpos(cx, cy, pix) * spin(min_gfx_slope), 0x40, 0x40, PPR::ZERO);
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curvepoint(hpxy(rad/4, 0));
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curvepoint(hpxy(0, rad));
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curvepoint(hpxy(-rad/4, 0));
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curvepoint(hpxy(rad/4, 0));
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queuecurve(sId * atscreenpos(cx, cy, pix) * spin(90._deg + slope), 0xFF, 0x40C040FF, PPR::ZERO);
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// compass
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cx -= rad * 1.2;
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for(int i=0; i<360; i++)
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curvepoint(atscreenpos(cx-cos(i * degree)*rad, cy-sin(i*degree)*rad, 1) * C0);
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queuecurve(sId, 0x000000FF, 0xFFFFFF80, PPR::ZERO);
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for(int d: {1}) {
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// d == +1: direction arrow
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// d == -1: compass
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curvepoint(hpxy(rad/4, 0));
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curvepoint(hpxy(0, rad));
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curvepoint(hpxy(-rad/4, 0));
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queuecurve(sId * atscreenpos(cx, cy, pix) * spin(d * (90*degree + heading_angle)), 0xFF, d > 0 ? 0x0000FFFF : 0xFF0000FF, PPR::ZERO);
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curvepoint(hpxy(rad/4, 0));
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curvepoint(hpxy(0, -rad));
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curvepoint(hpxy(-rad/4, 0));
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curvepoint(hpxy(rad/4, 0));
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queuecurve(sId * atscreenpos(cx, cy, pix) * spin(d * (90*degree + heading_angle)), 0xFF, 0xFFFFFFFF, PPR::ZERO);
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}
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// speed meter
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cx += rad * 3.4;
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for(int i=0; i<360; i++)
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curvepoint(atscreenpos(cx-cos(i * degree)*rad, cy-sin(i*degree)*rad, 1) * C0);
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queuecurve(sId, 0x000000FF, 0xFFFFFF80, PPR::ZERO);
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auto e_to_angle = [] (ld energy) {
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return 135*degree - 3 * atan(energy/10);
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};
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vector<ld> short_lines = {2, 3, 4, 6, 7, 8, 9, 30, 40, 60, 70, 80, 90, 100, 200, 300, 400, 500, 600, 700, 800, 900, 1000};
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for(auto h: short_lines) {
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auto a = e_to_angle(h);
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curvepoint(hpxy(-sin(a)*rad*.95, -cos(a)*rad*.95));
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curvepoint(hpxy(-sin(a)*rad*.85, -cos(a)*rad*.85));
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queuecurve(sId * atscreenpos(cx, cy, pix), 0xFF, 0, PPR::ZERO);
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}
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vector<ld> long_lines = {0, 1, 5, 10, 20, 50};
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for(auto h: long_lines) {
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auto a = e_to_angle(h);
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curvepoint(hpxy(-sin(a)*rad*.95, -cos(a)*rad*.95));
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curvepoint(hpxy(-sin(a)*rad*.75, -cos(a)*rad*.75));
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queuecurve(sId * atscreenpos(cx, cy, pix), 0xFF, 0, PPR::ZERO);
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displaystr(cx -sin(a)*rad*.65, cy -cos(a)*rad*.65, 0, 8, its(h), 0, 8);
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}
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|
curvepoint(hpxy(rad/4, 0));
|
|
curvepoint(hpxy(0, -rad));
|
|
curvepoint(hpxy(-rad/4, 0));
|
|
curvepoint(hpxy(rad/4, 0));
|
|
queuecurve(sId * atscreenpos(cx, cy, pix) * spin(e_to_angle(energy_in_squares())), 0xFF, 0xFF8080FF, PPR::ZERO);
|
|
|
|
cx += rad;
|
|
|
|
int tid = 0;
|
|
|
|
for(int i=0; i<isize(l->triangles); i++) {
|
|
bool have = collected_triangles & Flag(i);
|
|
color_t f = l->triangles[i].colors[6];
|
|
if(have) {
|
|
poly_outline = 0xFF;
|
|
}
|
|
else {
|
|
poly_outline = f;
|
|
f = 0x40;
|
|
}
|
|
|
|
queuepoly(sId * atscreenpos(cx+rad/2, cy+(tid&1?1:-1)*rad/3, pix * rad * 1.2) * spin(90*degree), cgi.shTriangle, f);
|
|
tid++;
|
|
if(tid == 2) { tid = 0; cx += rad/1.4; }
|
|
}
|
|
if(tid) cx += rad/1.4;
|
|
cx += 5;
|
|
|
|
int gid = 0;
|
|
for(auto& g: l->goals) {
|
|
bool gfailed = failed & Flag(gid);
|
|
bool gsuccess = goals & Flag(gid);
|
|
shiftmatrix T = sId * atscreenpos(cx+rad/2, cy+(gid-1)*rad/1.2, pix * rad * 1.2);
|
|
poly_outline = 0xFF; color_t f = darkena(g.color, 0, 0xFF);
|
|
if(gsuccess) {
|
|
queuepoly(T * spin(90*degree), cgi.shGrail, f);
|
|
displaystr(cx+rad, cy+(gid-1)*rad/1.2, 0, vid.fsize*.75, format_timer(l->current_score[gid]), 0, 0);
|
|
}
|
|
else {
|
|
poly_outline = f; f = 0x40;
|
|
queuepoly(T * spin(90*degree), cgi.shGrail, f);
|
|
if(gfailed) { poly_outline = 0xFF; queuepoly(T, cgi.shPirateX, 0xC00000FF); }
|
|
}
|
|
gid++;
|
|
}
|
|
|
|
quickqueue();
|
|
glflush();
|
|
|
|
displaystr(vid.xres - vid.fsize, vid.fsize*2, 0, vid.fsize * 2, format_timer(timer), 0, 16);
|
|
|
|
string s;
|
|
if(loaded_or_planned) s = "R";
|
|
else if(reversals) s = hr::format("+%d", reversals);
|
|
else return;
|
|
displaystr(vid.xres - vid.fsize, vid.fsize*4, 0, vid.fsize, s, 0, 16);
|
|
}
|
|
|
|
}
|