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hyperrogue/rogueviz/nilrider/save.cpp

211 lines
6.5 KiB
C++

namespace nilrider {
const string ver = "2.0";
string new_replay_name() {
time_t timer;
timer = time(NULL);
char timebuf[128];
strftime(timebuf, 128, "%y%m%d-%H%M%S", localtime(&timer));
return timebuf;
}
void save() {
#if CAP_SAVE
println(hlog, "save called");
fhstream f("nilrider.save", "wt");
println(f, "NilRider version ", ver);
for(auto l: all_levels) {
for(int i: {0,1}) {
int qg = isize(l->records[i]);
for(int g=0; g<qg; g++)
if(l->records[i][g]) {
println(f, "*RECORD");
println(f, l->name);
println(f, hr::format("%d %d %f", i, g, l->records[i][g]));
}
}
}
println(f, "*COLORS\n");
println(f, "*RLE\n");
for(auto l: all_levels) {
if(l->flags & nrlUserCreated) {
println(f, "*FILE");
println(f, l->filename);
}
for(auto& p: l->manual_replays) {
println(f, "*MANUAL");
println(f, l->name);
println(f, p.name);
fprintf(f.f, "%08x %08x %08x %08x\n", p.cs.wheel1, p.cs.wheel2, p.cs.seat, p.cs.seatpost);
println(f, isize(p.headings));
for(auto t: p.headings) println(f, t.first, " ", t.second);
println(f);
}
for(auto& p: l->plan_replays) {
println(f, "*PLANNING");
println(f, l->name);
println(f, p.name);
fprintf(f.f, "%08x %08x %08x %08x\n", p.cs.wheel1, p.cs.wheel2, p.cs.seat, p.cs.seatpost);
println(f, isize(p.plan));
for(auto t: p.plan) println(f, hr::format("%.6f %.6f %.6f %.6f", t.at[0], t.at[1], t.vel[0], t.vel[1]));
println(f);
}
}
#endif
}
level *level_by_name(string s) {
for(auto l: all_levels) if(l->name == s) return l;
println(hlog, "error: unknown level ", s);
return nullptr;
}
colorscheme load_colors(fhstream& f, bool have_colors) {
if(have_colors) {
colorscheme s(0);
fscanf(f.f, "%x%x%x%x", &s.wheel1, &s.wheel2, &s.seat, &s.seatpost);
return s;
}
else {
colorscheme s(2);
return s;
}
}
vector<pair<int, int>> apply_rle(const vector<int>& data) {
vector<pair<int, int>> rle;
if(data.empty()) return rle;
int last = data[0], count = 0;
for(int v: data) {
if(v != last) { rle.emplace_back(count, last); count = 0; last = v; }
count++;
}
rle.emplace_back(count, last);
return rle;
}
void load() {
#if CAP_SAVE
bool have_colors = false;
bool have_rle = false;
println(hlog, "load called");
fhstream f("nilrider.save", "rt");
if(!f.f) return;
string ver = scanline_noblank(f);
while(!feof(f.f)) {
string s = scanline_noblank(f);
if(s == "") continue;
if(s == "*COLORS") { have_colors = true; continue; }
if(s == "*RLE") { have_rle = true; continue; }
if(s == "*FILE") {
string s1 = scanline_noblank(f);
try { load_level(s1, false); }
catch(hr_exception& e) { println(hlog, "error: could not load level ", s1, ", reason: ", e.what()); }
}
if(s == "*MANUAL") {
string lev = scanline_noblank(f);
string name = scanline_noblank(f);
colorscheme cs = load_colors(f, have_colors);
vector<pair<int, int>> headings;
int size = scan<int> (f);
if(size < 0 || size > 1000000) throw hstream_exception();
if(have_rle) {
println(hlog, "reading a RLE replay");
for(int i=0; i<size; i++) { int rep = scan<int>(f); headings.emplace_back(rep, scan<int>(f)); }
}
else {
vector<int> h;
for(int i=0; i<size; i++) h.emplace_back(scan<int>(f));
headings = apply_rle(h);
println(hlog, "converted ", isize(h), " to ", isize(headings));
}
auto l = level_by_name(lev);
if(l) l->manual_replays.emplace_back(manual_replay{name, cs, std::move(headings)});
continue;
}
if(s == "*PLANNING") {
string lev = scanline_noblank(f);
string name = scanline_noblank(f);
colorscheme cs = load_colors(f, have_colors);
plan_t plan;
int size = scan<int> (f);
if(size < 0 || size > 1000000) throw hstream_exception();
plan.resize(size, {C0, C0});
for(int i=0; i<size; i++) scan(f, plan[i].at[0], plan[i].at[1], plan[i].vel[0], plan[i].vel[1]);
auto l = level_by_name(lev);
if(l) l->plan_replays.emplace_back(plan_replay{name, cs, std::move(plan)});
continue;
}
if(s == "*RECORD") {
string lev = scanline_noblank(f);
int i = scan<int>(f);
int g = scan<int>(f);
ld t = scan<ld>(f);
auto l = level_by_name(lev);
if(l) {
int qg = isize(l->goals);
if(i < 0 || i > 1) println(hlog, "error: wrong number as i");
if(g < 0 || g >= qg) println(hlog, "error: wrong goal index");
l->records[i].resize(qg, 0);
l->records[i][g] = t;
}
continue;
}
println(hlog, "error: unknown content ", s);
}
#endif
}
void level::load_plan_as_ghost(plan_replay& r) {
vector<timestamp> history_backup;
swap(history_backup, history);
swap(r.plan, plan);
history.clear();
history.push_back(start);
while(true) {
int s = isize(history);
if(!simulate()) break;
if(isize(history) == s) break;
}
println(hlog, "a history of length ", isize(history), " becomes a ghost");
ghosts.emplace_back(ghost{r.cs, {}});
auto& g = ghosts.back();
g.history = std::move(history);
swap(history_backup, history);
swap(r.plan, plan);
}
vector<timestamp> level::headings_to_history(manual_replay& r) {
vector<timestamp> history;
timestamp cur = start;
for(auto [qty, h]: r.headings) {
println(hlog, "pair: ", tie(qty, h));
for(int i=0; i<qty; i++) {
if(cur.on_surface) cur.heading_angle = int_to_heading(h);
history.push_back(cur);
if(!cur.tick(this)) return history;
}
}
return history;
}
void level::load_manual_as_ghost(manual_replay& r) {
ghosts.emplace_back(ghost{r.cs, headings_to_history(r) });
}
void save_manual_replay() {
vector<int> ang;
if(curlev->history.back().timer < 5) { addMessage("too short -- not saving"); return; }
for(auto& h: curlev->history) ang.push_back(h.on_surface ? heading_to_int(h.heading_angle) : 0);
curlev->manual_replays.emplace_back(manual_replay{new_replay_name(), my_scheme, apply_rle(ang)});
save();
}
void level::load_all_ghosts() {
for(auto& g: plan_replays) load_plan_as_ghost(g);
for(auto& g: manual_replays) load_manual_as_ghost(g);
}
}