1
0
mirror of https://github.com/zenorogue/hyperrogue.git synced 2024-11-23 13:07:16 +00:00
hyperrogue/rogueviz/dynamic-wfc.cpp
Arthur O'Dwyer ced3bbcad4 Qualify calls to format
C++20 introduces `std::format` and we `using namespace std`,
so some of these would be ambiguous in C++20.
2023-08-21 10:18:44 -07:00

462 lines
12 KiB
C++

#include "../hyper.h"
// an implementation of WFC-like constraint satisfaction problem using polytime dynamic programming
// see: https://arxiv.org/abs/2002.09534
// usage: hyper -canvas 0 -dynamic-wfc [constraint] [cutoff] [radius]
// where constraint is one of:
// 0: every cell has 2 yellow neighbors
// 1: every cell's neighborhood has two consistent regions
// 2: every cell's neighborhood has four consistent regions
// 3: landscape: every cell has 1 consistent region of next type and 1 region of prev type
// cutoff is cut off from the disk
// radius is the radius of the disk to generate
namespace hr {
namespace dynamic_wfc {
bool animated = false;
vector<cell*> generate_pd_list(celllister& cl) {
cell *croot = cl.lst.back();
cellwalker cw(croot, 0);
while(cl.listed(cw.peek())) cw++;
while(!cl.listed(cw.peek())) cw++;
vector<cell*> currpath = {};
cellwalker cw1 = cw;
vector<cell*> result;
// int steps = 0;
auto push = [&] (cell *c) {
// println(hlog, "push ", c, " at ", isize(currpath));
currpath.push_back(c);
result.push_back(c);
};
auto pop = [&] () {
// println(hlog, "pop ", currpath.back(), " at ", isize(currpath)-1);
currpath.pop_back();
};
auto replace = [&] (int pos, cell *c) {
// println(hlog, "replace ", currpath[pos], " to ", c, " at ", pos, "/", isize(currpath));
currpath[pos] = c;
result.push_back(c);
};
push(croot);
while(true) {
cw += wstep;
cw++;
while(!cl.listed(cw.peek())) cw++;
cell *cn = cw.at;
// cn->item = itGold;
// println(hlog, "at ", cn, " [", steps++, "]");
int cd = celldistance(cn, croot) + 1;
if(cd > isize(currpath))
push(cn);
else {
if(cd < isize(currpath))
pop();
if(currpath.back() != cn) {
int moves = 1;
while(celldistance(currpath[cd-1-moves], cn) > moves) {
moves++;
continue;
}
while(moves > 0) {
moves--;
forCellEx(cx, currpath[cd-2-moves])
if(celldistance(cx, cn) == moves)
replace(cd-1-moves, cx);
}
}
}
/*
cell *last = nullptr;
for(cell *c: currpath) {
if(last) print(hlog, " ", celldistance(c, last), " ");
last = c;
print(hlog, c);
}
println(hlog); */
for(int i=1; i<isize(currpath); i++)
if(celldistance(currpath[i-1], currpath[i]) != 1)
println(hlog, "PD error");
if(cw == cw1) break;
}
return result;
}
struct ttrans {
int news;
int olds;
float proportion;
char id;
};
vector<ttrans> trans;
vector<cell*> ctf;
vector<cell*> global_list;
int wfctype, wfcrad, cutoff;
void wfc_clear() {
trans.clear();
ctf.clear();
global_list.clear();
}
void wfc_build() {
int code_at = trans.back().news;
int cpos = isize(ctf);
for(int i=isize(trans)-1; i>=0; i--) {
auto& tri = trans[i];
if(tri.news == code_at) {
// println(hlog, tie(tri.news, tri.olds, tri.proportion, tri.where, tri.id));
if(hrandf() < tri.proportion) {
cell *c = ctf[--cpos];
int id = tri.id;
switch(wfctype) {
case 0:
if(id == 0) c->wall = waNone, c->landparam = 0xFF4040;
else c->wall = waNone, c->landparam = 0xFFFF40;
break;
case 1:
if(id == 0) c->wall = waNone, c->landparam = 0x4040FF;
else c->wall = waNone, c->landparam = 0x40FF40;
break;
case 2:
if(id == 0) c->wall = waNone, c->landparam = 0x8080FF;
else c->wall = waNone, c->landparam = 0x202020;
break;
case 3:
if(id == 0) c->wall = waNone, c->landparam = 0xC08080;
else if(id == 1) c->wall = waNone, c->landparam = 0x80C080;
else c->wall = waNone, c->landparam = 0x8080C0;
break;
}
// println(hlog, code_at, " -> ", tri.olds, " [", tri.where, "=", tri.id, "]");
code_at = tri.olds;
}
}
}
}
void wfc() {
int rad = wfcrad;
vector< vector< vector<cell*> > > new_neighborhoods;
map<cell*, int> lorder;
map<cell*, int> multiplicity;
set<cell*> consider;
celllister cl(cwt.at, rad, 999999, nullptr);
for(cell *c: cl.lst) setdist(c, 7, nullptr);
auto l = generate_pd_list(cl);
int ls = isize(l);
for(int i=0; i<ls; i++) lorder[l[i]] = i;
println(hlog, "lorder[0] = ", l[0]);
for(int i=0; i<ls; i++) {
// int dctr = celldistance(l[i], cwt.at);
int dfirst = celldistance(l[i], l[0]);
// int dtotal = celldistance(l[0], cwt.at);
//if(dtotal == dfirst + dctr && dfirst < cutoff) ;
//else
if(dfirst >= cutoff)
consider.insert(l[i]);
}
new_neighborhoods.resize(ls);
for(cell *c: cl.lst) {
bool ok = true;
forCellEx(c1, c) if(!consider.count(c1)) ok = false;
if(!ok) continue;
vector<cell*> nn = {c};
forCellEx(c1, c) nn.push_back(c1);
for(auto cx: nn) multiplicity[cx]++;
int max_order = -1;
for(auto cx: nn) max_order = max(max_order, lorder[cx]);
new_neighborhoods[max_order].push_back(nn);
}
int typecount = 2;
if(wfctype == 3) typecount++;
vector<cell*> inpath;
typedef unsigned long long code_t;
const int cpo = 2;
const code_t mask = (1<<cpo)-1;
struct freqdata {
code_t code;
int id;
double prob;
};
vector<freqdata> freq = { freqdata{0, 0, 1} };
vector<freqdata> nfreq;
trans.clear();
int nextcode = 1;
int all = 2 << (cpo * 8);
vector<double> mul(all, 0);
for(int a=0; a<all; a++) {
vector<int> v;
int a0 = a;
while(a0) { v.push_back(a0 & mask); a0 >>= cpo; }
if(isize(v) < 2) continue;
v.pop_back();
int cur = v.back();
v.pop_back();
int changes = 0;
for(int i=1; i<isize(v); i++) if(v[i] == 1 && v[i-1] == 0) changes++;
if(v[0] == 1 && v.back() == 0) changes++;
int nes = 0;
for(int vv: v) nes += vv;
switch(wfctype) {
case 0:
mul[a] = nes == 2;
break;
case 1:
mul[a] = changes == 1;
break;
case 2:
mul[a] = changes == 2;
break;
case 3: {
int ca=0, cb=0, cc=0, cd=0, ce=0;
int cur1 = (cur+1) % 3;
int cur2 = (cur+2) % 3;
int same = 0;
int in1 = 0;
int in2 = 0;
for(int i=0; i<isize(v); i++) {
auto va = v[i], vb = v[(i+1)%isize(v)];
if(va == cur && vb == cur1) ca++;
if(va == cur && vb == cur2) cb++;
if(va == cur1 && vb == cur) cc++;
if(va == cur2 && vb == cur) cd++;
if(va == cur1 && vb == cur2) ce++;
if(va == cur2 && vb == cur1) ce++;
if(va == cur) same++;
if(va == cur1) in1++;
if(va == cur2) in2++;
}
mul[a] = ca==1 && cb==1 && cc==1 && cd==1 && ce==0; // && in1 >= 2; // && in2 >= 2;
if(mul[a]) println(hlog, v, cur, " => ", mul[a]);
break;
}
}
// println(hlog, a, ": ", v, " -> ", mul[a]);
}
/*
mul[0] = 0;
for(int a=0; a<8; a++)
mul[1<<a] = 1;
*/
long long tfreq = 0;
if(animated)
for(int j=0; j<ls; j++)
for(auto& nns: new_neighborhoods[j]) for(auto c: nns) c->landparam = 0x202020;
for(int i=0; i<ls; i++) if(consider.count(l[i])) {
tfreq += isize(freq);
string s = lalign(0, i, "/", ls, ": freqs = ", isize(freq), " inpath ", isize(inpath));
println(hlog, s);
if(animated) {
for(int j=0; j<i; j++)
for(auto& nns: new_neighborhoods[j]) for(auto c: nns) c->landparam = multiplicity[c] ? 0xFFFF00 : 0x00FF00;
for(auto& nns: new_neighborhoods[i]) for(auto c: nns) c->landparam = 0xFFFFFF;
history::progress(s);
}
inpath.push_back(l[i]);
int sh = cpo * (isize(inpath)-1);
for(auto& p: freq) if(p.prob) for(char c=0; c<typecount; c++) {
nfreq.emplace_back(p);
nfreq.back().code |= (code_t(c) << sh);
}
freq = std::move(nfreq);
nfreq = {};
// println(hlog, "inpath = ", inpath);
// println(hlog, "freqs = ", isize(freq));
if(isize(freq) > 500000000) {
println(hlog, "freq overflow");
exit(3);
}
fflush(stdout);
global_list = cl.lst;
for(auto& nns: new_neighborhoods[i]) {
// println(hlog, "acknowledge ", nns);
fflush(stdout);
vector<int> sids;
for(auto cz: nns) {
for(int id=0; id<isize(inpath); id++) if(inpath[id] == cz) sids.push_back(id);
}
for(auto& p: freq) {
unsigned code = 1;
for(int v: sids) code = (code << cpo) | ((p.code >> (cpo*v)) & mask);
p.prob *= mul[code];
}
for(auto cz: nns) {
multiplicity[cz]--;
if(multiplicity[cz] == 0) {
ctf.push_back(cz);
// println(hlog, "remove ", cz, " (#", lorder[cz], ") from ", inpath);
fflush(stdout);
int is = isize(inpath)-1;
int id = 0;
while(id <= is && inpath[id] != cz) id++;
if(id > is) {
println(hlog, "error");
exit(4);
}
inpath[id] = inpath[is];
inpath.resize(is);
for(auto& p: freq) if(p.prob) {
nfreq.push_back(p);
int tid = (p.code >> (cpo*id)) & mask;
code_t& s = nfreq.back().code;
s &=~ (mask << (cpo*id));
if(id < is) s |= ((s >> (cpo*is)) & mask) << (cpo*id);
s &=~ (mask << (cpo*is));
// s.resize(is);
// if(id < is) s[id] = p.code[is];
nfreq.back().id = (nfreq.back().id << cpo) | tid;
}
freq.clear();
sort(nfreq.begin(), nfreq.end(), [] (const freqdata& a, const freqdata& b) { return a.code < b.code; });
for(int i=0; i<isize(nfreq); i++) {
auto &next = nfreq[i];
if(i == 0 || nfreq[i].code != nfreq[i-1].code) {
freq.push_back(nfreq[i]);
freq.back().id = nextcode++;
freq.back().prob = 0;
}
auto& group = freq.back();
group.prob += next.prob;
ttrans nt;
nt.news = group.id;
nt.olds = next.id >> cpo;
nt.proportion = next.prob / group.prob;
nt.id = next.id & mask;
trans.push_back(nt);
}
nfreq.clear();
}
}
}
}
if(isize(freq)) println(hlog, "last freq = ", freq[0].prob);
println(hlog, "freq size = ", isize(freq));
println(hlog, "tfreq = ", hr::format("%lld", tfreq));
println(hlog, "trans size = ", isize(trans));
println(hlog, "next code = ", nextcode);
clearMessages();
wfc_build();
}
bool wfc_handleKey(int sym, int uni) {
if(sym == '5') {
wfc_build();
return true;
}
return false;
}
void hwrite(hstream& f, const ttrans& t) {
hwrite(f, t.news);
hwrite(f, t.olds);
hwrite(f, t.proportion);
hwrite(f, t.id);
}
void save(string s) {
fhstream f(s, "wb");
vector<int> indices;
for(auto cf: ctf)
for(int i=0; i<isize(global_list); i++)
if(global_list[i] == cf) indices.push_back(i);
hwrite(f, wfctype);
hwrite(f, cutoff);
hwrite(f, wfcrad);
hwrite(f, indices);
hwrite(f, trans);
}
auto wfc_hook =
addHook(hooks_args, 100, [] {
using namespace arg;
if(0) ;
else if(argis("-dynamic-wfc")) {
start_game();
shift(); wfctype = argi();
shift(); cutoff = argi();
shift(); wfcrad = argi();
wfc();
}
else if(argis("-dynamic-wfc-save")) {
shift(); save(args());
}
else if(argis("-wfc-regen-key")) {
rogueviz::rv_hook(hooks_handleKey, 100, wfc_handleKey);
}
else return 1;
return 0;
});
}
}