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hyperrogue/rogueviz/bringris.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

2104 lines
57 KiB
C++

// non-Euclidean falling block game, implemented using the HyperRogue engine
// Copyright (C) 2011-2021 Zeno Rogue, see 'hyper.cpp' for details
#ifdef BRINGRIS
#define CUSTOM_CAPTION "Bringris 1.6"
#define MAXMDIM 4
#define CAP_INV 0
#define CAP_COMPLEX2 0
#define CAP_EDIT 0
#ifdef BWEB
#define CAP_BT 0
#define CAP_SOLV 0
#endif
#define CAP_THREAD 0
// #define CAP_ZLIB 0
#define CAP_FILES 1
#define CAP_CONFIG 1
// #define CAP_ANIMATIONS 0
#define CAP_RUG 0
#define CAP_SHOT 0
#define CAP_SVG 0
#define CAP_PNG 0
#define CAP_WRL 0
#define CAP_TOUR 0
#define CAP_IRR 0
#define CAP_CRYSTAL 0
#define CAP_ARCM 0
#define CAP_HISTORY 0
#define CAP_STARTANIM 0
#define CAP_SAVE 0
#define CAP_TRANS 0
#ifdef BWEB
#include "../hyperweb.cpp"
#else
#include "../hyper.cpp"
#endif
#include "subquotient.cpp"
#define SUBQ
#endif
#include "../hyper.h"
#define solnil (nil || sol)
namespace hr {
namespace subquotient {
#ifndef SUBQ
void create_subquotient(int qty = -1, int id = 0);
#endif
extern eGeometry gSubquotient;
}
namespace bringris {
local_parameter_set lps_bringris("bringris:");
local_parameter_set lps_bringris_explore("bringris:explore:", &lps_bringris);
local_parameter_set lps_bringris_play("bringris:play:", &lps_bringris);
multi::config scfg_bringris;
struct bgeometry {
string name;
string cap;
flagtype flags;
reaction_t create;
};
enum eBringrisMove { bmDown, bmLeft, bmUp, bmRight, bmTurnLeft, bmTurnRight, bmDrop, bmFullDrop, bmPause, bmNothing, bmLast };
vector<string> move_names = { "move down", "move left", "move up", "move right", "turn left", "turn right", "drop by one", "full drop", "pause", "do nothing" };
int camera_level;
ld ang = 0, cur_ang = 0;
int lti;
int bgeom = 0;
int max_piece;
bool rotate_allowed = false;
bool in_bringris;
bool use_raycaster = true;
bool flashes = true;
int last_adjust, when_t;
transmatrix tView, pView;
cell* ncenter;
cell *well_center;
vector<cell*> level;
vector<cell*> out_level;
map<cell*, int> center_distance;
bool pro_game;
int well_size = 10;
int camera = 3;
int facing_mod = 0;
int draw_per_level = 2000;
int shape_id, next_shape_id;
cellwalker at;
int move_started;
int move_at;
int completed;
int bricks, cubes;
ld score;
bool paused;
bool explore;
enum eState {
tsPreGame, tsFalling, tsBetween, tsCollect, tsGameover
};
eState state = tsPreGame;
constexpr flagtype HYPERBOLIC = 1;
constexpr flagtype ORBIFOLD = 2;
constexpr flagtype SECRET = 4;
constexpr flagtype NONORIENTABLE = 8;
constexpr flagtype SPHERICAL = 16;
constexpr flagtype EUCLIDEAN = 32;
constexpr flagtype SUBQUOTIENT = 64;
constexpr flagtype HDUAL = 128;
constexpr flagtype BOUNDED_WELL = 256;
constexpr flagtype ASYMMETRIC_ONLY = 512;
constexpr flagtype FLAT_ONLY = 1024;
cell *get_center();
cell *shift_block_target(int dir);
void shift_block(int dir, bool camera_only = false);
void rotate_block(int dir, bool camera_only = false);
vector<bgeometry> bgeoms = {
{"Bring surface", "the original Bringris geometry", HYPERBOLIC, [] {
using namespace fieldpattern;
current_extra = 2;
auto& gxcur = fgeomextras[current_extra];
while(isize(gxcur.primes) < 1) nextPrime(gxcur);
fgeomextras[current_extra].current_prime_id = 0;
enableFieldChange();
set_geometry(gFieldQuotient);
gp::param = gp::loc(1, 1);
set_variation(eVariation::unrectified);
set_geometry(gProduct);
max_piece = 4;
rotate_allowed = false;
}},
{"torus", "Euclidean level geometry", EUCLIDEAN, [] {
auto& T0 = euc::eu_input.user_axes;
T0[0][0] = 5;
T0[0][1] = 0;
T0[1][0] = 0;
T0[1][1] = 5;
euc::eu_input.twisted = 0;
set_geometry(gEuclidSquare);
set_variation(eVariation::pure);
set_geometry(gProduct);
max_piece = 4;
rotate_allowed = true;
}},
{"Cube", "spherical level geometry", SPHERICAL, [] {
set_geometry(gSmallSphere);
set_variation(eVariation::pure);
set_geometry(gProduct);
max_piece = 3;
rotate_allowed = false;
}},
{"Klein bottle", "non-orientable manifold", EUCLIDEAN | NONORIENTABLE, [] {
auto& T0 = euc::eu_input.user_axes;
T0[0][0] = 5;
T0[0][1] = 0;
T0[1][0] = 0;
T0[1][1] = 5;
euc::eu_input.twisted = 8;
set_geometry(gEuclidSquare);
set_variation(eVariation::pure);
set_geometry(gProduct);
max_piece = 4;
rotate_allowed = true;
}},
{"pentagons", "different tiles on the Bring surface", HYPERBOLIC | HDUAL, [] {
using namespace fieldpattern;
current_extra = 2;
auto& gxcur = fgeomextras[current_extra];
while(isize(gxcur.primes) < 1) nextPrime(gxcur);
fgeomextras[current_extra].current_prime_id = 0;
enableFieldChange();
set_geometry(gFieldQuotient);
set_variation(eVariation::pure);
set_geometry(gProduct);
max_piece = 4;
rotate_allowed = false;
}},
{"double cube", "six squares around a vertex", HYPERBOLIC, [] {
using namespace fieldpattern;
current_extra = 3;
auto& gxcur = fgeomextras[current_extra];
while(isize(gxcur.primes) < 1) nextPrime(gxcur);
fgeomextras[current_extra].current_prime_id = 0;
enableFieldChange();
set_geometry(gFieldQuotient);
gp::param = gp::loc(1, 1);
set_variation(eVariation::unrectified);
set_geometry(gProduct);
max_piece = 3;
rotate_allowed = true;
}},
{"30/6", "six squares around a vertex", HYPERBOLIC, [] {
using namespace fieldpattern;
current_extra = 3;
auto& gxcur = fgeomextras[current_extra];
while(isize(gxcur.primes) < 1) nextPrime(gxcur);
fgeomextras[current_extra].current_prime_id = 2;
enableFieldChange();
set_geometry(gFieldQuotient);
gp::param = gp::loc(1, 1);
set_variation(eVariation::unrectified);
set_geometry(gProduct);
max_piece = 4;
rotate_allowed = true;
}},
{"42", "seven squares around a vertex", HYPERBOLIC, [] {
using namespace fieldpattern;
current_extra = 4;
auto& gxcur = fgeomextras[current_extra];
while(isize(gxcur.primes) < 1) nextPrime(gxcur);
fgeomextras[current_extra].current_prime_id = 0;
enableFieldChange();
set_geometry(gFieldQuotient);
gp::param = gp::loc(1, 1);
set_variation(eVariation::unrectified);
set_geometry(gProduct);
max_piece = 4;
rotate_allowed = false;
}},
{"bounded well", "five squares around a vertex", BOUNDED_WELL, [] {
set_geometry(g45);
gp::param = gp::loc(1, 1);
set_variation(eVariation::unrectified);
set_geometry(gProduct);
max_piece = 4;
rotate_allowed = false;
}},
{"mirrored Bring", "hyperbolic and non-orientable", HYPERBOLIC | NONORIENTABLE | ASYMMETRIC_ONLY, [] {
set_geometry(gBring);
gp::param = gp::loc(1, 1);
set_variation(eVariation::unrectified);
start_game();
subquotient::create_subquotient(2);
set_geometry(gProduct);
max_piece = 4;
rotate_allowed = false;
}},
{"giant", "like mirrored Bring but much larger", HYPERBOLIC | NONORIENTABLE, [] {
using namespace fieldpattern;
current_extra = 2;
auto& gxcur = fgeomextras[current_extra];
while(isize(gxcur.primes) < 1) nextPrime(gxcur);
fgeomextras[current_extra].current_prime_id = 1;
enableFieldChange();
set_geometry(gFieldQuotient);
gp::param = gp::loc(1, 1);
set_variation(eVariation::unrectified);
subquotient::create_subquotient(2);
set_geometry(gProduct);
max_piece = 5;
rotate_allowed = false;
well_size = 6;
}},
{"orbifold", "one fifth of the giant", HYPERBOLIC | NONORIENTABLE | ORBIFOLD, [] {
using namespace fieldpattern;
current_extra = 2;
auto& gxcur = fgeomextras[current_extra];
while(isize(gxcur.primes) < 1) nextPrime(gxcur);
fgeomextras[current_extra].current_prime_id = 1;
enableFieldChange();
set_geometry(gFieldQuotient);
gp::param = gp::loc(1, 1);
set_variation(eVariation::unrectified);
subquotient::create_subquotient(10);
set_geometry(gProduct);
max_piece = 4;
rotate_allowed = false;
}},
{"torus: shear", "Nil geometry: are you sure you want this?", SECRET, [] {
nilv::nilperiod = make_array(5, 0, 5);
// nilv::set_flags();
set_geometry(gNil);
max_piece = 4;
rotate_allowed = false;
}},
#if CAP_SOLV
{"torus: Arnold's Cat", "Solv geometry: flat shapes are crazy enough", SECRET | FLAT_ONLY, [] {
asonov::period_xy = 5;
asonov::period_z = 0;
asonov::set_flags();
set_geometry(gArnoldCat);
max_piece = 2;
rotate_allowed = false;
}},
#endif
};
void create_game();
void enable_bgeom() {
stop_game_and_switch_mode(rg::nothing);
well_size = 10;
bgeoms[bgeom].create();
start_game();
create_game();
state = tsPreGame;
}
void enable_bgeom(int b) {
bgeom = b;
enable_bgeom();
}
flagtype bflags() { return bgeoms[bgeom].flags; }
using code_t = vector<pair<int, int>>;
struct piecedata {
code_t code;
int multi;
int penalty;
int symmetries;
int count;
};
vector<piecedata> piecelist;
map<set<cell*>, int> seen_blocks;
bool listed(const vector<cellwalker>& v, cell* c) {
for(auto cw: v) if(cw.at == c) return true;
return false;
}
int down_dir() { return nil ? 4 : sol ? 0 : cwt.at->type-1; }
int up_dir() { return nil ? 1 : sol ? 6 : cwt.at->type-2; }
cell *get_at(cell *lev, int z) {
if(mproduct)
return hybrid::get_at(lev, z);
else {
// auto co = nilv::get_coord(lev->master);
// co[2] += z * co[0];
// co[1] = z;
// return nilv::get_heptagon_at(co)->c7;
while(z<0) z++, lev=lev->cmove(up_dir());
while(z>0) z--, lev=lev->cmove(down_dir());
return lev;
}
}
int get_z(cell* c) {
if(mproduct)
return hybrid::get_where(c).second;
else if(nil)
return nilv::get_coord(c->master)[1];
else if(sol)
return asonov::get_coord(c->master)[2];
else
exit(1);
}
pair<cell*, int> get_where(cell *what) {
if(mproduct)
return hybrid::get_where(what);
else {
int z = get_z(what);
int zm = z;
while(zm>0) what = what->cmove(up_dir()), zm--;
while(zm<0) what = what->cmove(down_dir()), zm++;
return {what, z};
// co[2] -= co[1] * co[0];
// co[1] = 0;
// cell *c = nilv::get_heptagon_at(co)->c7;
// return {c, z};
}
}
set<cell*> as_set(const vector<cellwalker>& shape) {
set<cell*> res;
for(auto sh: shape) res.insert(sh.at);
return res;
}
bool same(const vector<cellwalker>& shape, const vector<cellwalker>& shape2) {
set<cell*> allcells;
if(isize(shape) != isize(shape2)) return false;
for(auto sh: shape) allcells.insert(sh.at);
for(auto sh: shape2) allcells.erase(sh.at);
return allcells.empty();
}
cellwalker flatspin(cellwalker cw, int i) {
if(solnil)
cw.spin = i;
else
cw.spin = gmod(cw.spin + (cw.mirrored ? -i : i), cw.at->type - (mhybrid ? 2 : 0));
return cw;
}
int add_dir(cellwalker orig, int i, int sym = 0) {
if(mproduct) {
if(i >= orig.at->type-2) {
if(sym&2) i ^= (orig.at->type-1) ^ (orig.at->type-2);
return i;
}
else {
if(sym&1) i = -i;
return flatspin(orig, i).spin;
}
}
return i;
}
cellwalker add(cellwalker orig, int i, int sym = 0) {
if(mproduct) {
if(i >= orig.at->type-2) {
if(sym&2) i ^= (orig.at->type-1) ^ (orig.at->type-2);
orig.at = orig.at->cmove(i);
return orig;
}
else {
if(sym&1) i = -i;
return flatspin(orig, i) + wstep;
}
}
return orig + i + wstep;
}
vector<cellwalker> build_from(const code_t& code, cellwalker start, int sym = 0) {
vector<cellwalker> all = {start};
for(auto c: code)
all.push_back(add(all[c.first], c.second, sym));
return all;
}
vector<transmatrix> build_shape_matrices(const code_t& code, cellwalker start, int sym = 0) {
vector<cellwalker> all = {start};
vector<transmatrix> allm = {Id};
for(auto c: code) {
all.push_back(add(all[c.first], c.second, sym));
allm.push_back(allm[c.first] * currentmap->adj(all[c.first].at, add_dir(all[c.first], c.second, sym)));
}
return allm;
}
int penalty(const vector<cellwalker>& shape, const code_t& code) {
int p = 0;
if(mproduct) {
int bad = shape[0].at->type-1;
for(auto co: code) if(co.second == bad)
p += 1000;
}
map<cell*, int> dists;
for(auto cw: shape) dists[cw.at] = 99;
dists[shape[0].at] = 0;
for(int i=0; i<isize(shape); i++)
for(auto c1: shape)
for(auto c2: shape)
if(neighborId(c1.at, c2.at) != -1)
dists[c2.at] = min(dists[c2.at], dists[c1.at] + 1);
for(auto d: dists) p += d.second * 10;
for(auto c: code) if(c.second == 0 || c.second == 2) p++;
if(solnil)
for(auto s: shape)
if(get_z(s.at) > get_z(shape[0].at))
p += 10000;
if(bflags() & HDUAL) {
for(auto s: shape)
if(get_z(s.at) > get_z(shape[0].at))
p += 20000;
/* if(!dists.count(shape[0].at->move(2)))
p += 40000;
if(!dists.count(shape[0].at->move(3)))
p += 20000; */
}
return p;
}
bool builds(const vector<cellwalker>& shape, const code_t& code, int sym = 0, int eliminate = -1) {
if(isize(shape) != isize(code)+1) return false;
int ori = (solnil) ? 1 : mproduct ? shape[0].at->type-2 : shape[0].at->type;
for(auto sh: shape) for(int i=0; i<ori; i++) {
vector<cellwalker> shape2 = build_from(code, cellwalker(sh.at, i), sym);
if(eliminate != -1) seen_blocks.emplace(as_set(shape2), eliminate);
if(same(shape, shape2))
return true;
}
return false;
}
void generate_shapes_rec(vector<cellwalker>& sofar, code_t& code, int cnt) {
if(isize(sofar) == cnt) {
int p = penalty(sofar, code);
auto ass = as_set(sofar);
if(seen_blocks.count(ass)) {
auto& pc = piecelist[seen_blocks[ass]];
if(p < pc.penalty) pc.penalty = p, pc.code = code;
pc.multi++;
return;
}
int id = 0;
for(auto& pc: piecelist) {
if(builds(sofar, pc.code, 0, id)) {
if(p < pc.penalty) pc.penalty = p, pc.code = code;
pc.multi++;
return;
}
id++;
}
int syms = 0;
bool invalid = false;
for(int i: {0,1,2,3}) if(builds(sofar, code, i)) {
syms++;
if((bflags() & ASYMMETRIC_ONLY) && i == 1 && cnt >= 4)
invalid = true;
}
if(invalid) return;
bool vertical = true;
for(auto c: code) if(c.second < 4) vertical = false;
if(vertical) syms *= 2;
if(isize(code) == 0) syms = 1;
piecelist.push_back(piecedata{code, 1, p, syms, 0});
return;
}
for(int i=0; i<isize(sofar); i++)
for(int t=0; t<sofar[i].at->type; t++) {
if(sol && !among(t, 4, 5, 10, 11)) continue;
cellwalker ncw = add(sofar[i], t);
if(listed(sofar, ncw.at)) continue;
code.emplace_back(i, t);
sofar.push_back(ncw);
generate_shapes_rec(sofar, code, cnt);
sofar.pop_back();
code.pop_back();
}
}
void generate_shapes(int cnt) {
vector<cellwalker> cws = { get_at(get_center(), -well_size - 1) };
code_t co = {};
generate_shapes_rec(cws, co, cnt);
}
void list_all() {
println(hlog, "number of shapes = ", isize(piecelist));
// for(auto sh: piecelist) println(hlog, "multi=", sh.multi, " penalty=", sh.penalty, " syms=", sh.symmetries, " => ", sh.code);
}
void water_shape() {
auto shape = build_from(piecelist[shape_id].code, at);
for(auto c: shape)
c.at->wall = waSea;
}
set<cell*> to_disappear;
color_t hipso[] = {
0x3030C0,
0x6060FF,
0x9090FF,
0xFFFFFF,
0x008000,
0x40FF00,
0xFFFF00,
0xFF8000,
0xFF0000,
0x800000,
0x400040,
0x500050,
0x600060
};
color_t get_hipso(ld y) {
y += 12;
if(well_size <= 5) y *= 2;
return hipso[gmod(y, 13)];
}
void draw_shape() {
auto shape = build_from(piecelist[shape_id].code, at);
for(auto c: shape) {
int y = -get_z(c.at);
c.at->wall = waWaxWall, c.at->landparam = get_hipso(y);
}
ray::reset_raycaster_map();
}
bool shape_drawn() {
auto shape = build_from(piecelist[shape_id].code, at);
for(auto c: shape)
return c.at->wall == waWaxWall;
return false;
}
void remove_shape() {
auto shape = build_from(piecelist[shape_id].code, at);
for(auto c: shape)
c.at->wall = waNone;
ray::reset_raycaster_map();
}
bool shape_conflict(cellwalker cw) {
auto shape = build_from(piecelist[shape_id].code, cw);
/* self-conflict possible in the orbifold */
for(int i=0; i<isize(shape); i++) for(int j=0; j<i; j++)
if(shape[i].at == shape[j].at)
return true;
for(auto c: shape)
if(c.at->wall)
return true;
return false;
}
ld current_move_time_limit() {
return 50000 * pow(.9, completed) + 10000. / (1 + completed);
}
int turn_animation = 500;
int collect_animation = 300;
int choose_piece() {
ld total = 0;
int sel = 0;
ld lowest = 100000;
for(auto &p: piecelist)
lowest = min(lowest, p.count * 1. / p.symmetries);
vector<tuple<int,int,ld>> probs;
for(int i=0; i<isize(piecelist); i++) {
auto& p = piecelist[i];
double cnt = p.symmetries * exp(log(.5) * (p.count * 1. / p.symmetries - lowest));
probs.emplace_back(p.symmetries, p.count, cnt);
total += cnt;
if(randd() < cnt / total)
sel = i;
}
// println(hlog, "probs = ", probs);
piecelist[sel].count++;
return sel;
}
void reset_view();
void set_tview(transmatrix T);
void new_piece() {
if(well_center && true) {
again:
if(get_where(at.at).first != well_center) {
at.at = get_at(get_where(at.at).first, -well_size - 1);
int d = center_distance[get_where(at.at).first];
for(int i=0; i<4; i++) {
auto mov = get_where(shift_block_target(i)).first;
if(center_distance.count(mov) && center_distance[mov] < d) {
shift_block(i, true);
goto again;
}
}
println(hlog, "failed to recenter");
}
while(at.spin) rotate_block(1, true);
}
at.at = get_at(get_where(at.at).first, -well_size - 1);
shape_id = next_shape_id;
next_shape_id = choose_piece();
if(shape_conflict(at)) {
playSound(cwt.at, "die-bomberbird");
state = tsGameover;
}
else {
draw_shape();
state = tsFalling;
move_started = ticks;
move_at = ticks + current_move_time_limit();
}
}
vector<int> by_level;
bool expert = true;
void find_lines() {
by_level.clear();
// println(hlog, "Removing levels");
for(int z=1; z<=well_size; z++) {
int ct = 0;
for(auto lev: level) {
cell *c = get_at(lev, -z);
ct += (c->wall ? 1 : 0);
}
by_level.push_back(ct);
}
// println(hlog, by_level, " / ", isize(level));
int points = 0;
if(expert) {
for(int z=1; z<=well_size; z++) if(by_level[z-1] >= isize(level)) {
points++;
for(auto lev: level) {
cell *c = get_at(lev, -z);
to_disappear.insert(c);
}
}
}
else {
// int lines_found = 0;
for(int z=1; z<=well_size; z++) {
for(auto lev: level) for(int d=0; d<lev->type; d++) {
cellwalker cw(get_at(lev, -z), d);
cellwalker cw0 = cw;
bool filled = true;
do {
if(!cw.at->wall) filled = false;
cw += wstep;
cw = flatspin(cw, lev->type/2);
}
while(cw != cw0);
if(filled) {
// lines_found = true;
do {
to_disappear.insert(cw.at);
cw += wstep;
cw = flatspin(cw, lev->type/2);
}
while(cw != cw0);
}
}
}
// println(hlog, "lines found = ", lines_found);
}
if(!to_disappear.empty()) {
move_at = ticks + collect_animation;
state = tsCollect;
score += 10000000. * points * (points+1.) / current_move_time_limit();
completed += points;
playSound(cwt.at, points == 1 ? "pickup-gold" : "orb-mind");
}
}
void disappear_lines() {
for(auto lev: level) {
int nz = 1;
for(int z=1; z<=well_size; z++) {
cell *c1 = get_at(lev, -z);
if(!to_disappear.count(c1)) {
cell *c0 = get_at(lev, -nz);
c0->wall = c1->wall;
c0->landparam = get_hipso(nz);
nz++;
}
}
while(nz <= camera_level) {
cell *c0 = get_at(lev, -nz);
c0->wall = waNone;
nz++;
}
}
to_disappear.clear();
state = tsBetween;
ray::reset_raycaster_map();
}
void state_loop() {
find_lines();
if(to_disappear.empty()) new_piece();
}
void fallen() {
draw_shape();
bricks++;
cubes += isize(piecelist[shape_id].code)+1;
state = tsBetween;
playSound(cwt.at, "closegate");
score += 20000000. / (current_move_time_limit() * 3 + ticks - move_started);
}
void drop() {
remove_shape();
cellwalker fall = at;
fall.at = fall.at->cmove(down_dir());
if(shape_conflict(fall))
fallen();
else {
at = fall;
draw_shape();
}
move_at = ticks + current_move_time_limit();
if(solnil) {
pView = pView * currentmap->adj(cwt.at, down_dir());
when_t = ticks + turn_animation;
}
}
void fulldrop() {
remove_shape();
cellwalker fall = at;
int no = 0;
auto last = fall;
while(true) {
last = fall;
fall.at = fall.at->cmove(down_dir());
if(shape_conflict(fall)) break;
no++;
}
playSound(cwt.at, "hit-crush2");
// println(hlog, "dropped by ", no);
fall = last;
at = fall;
draw_shape();
if(!no) fallen();
}
void verify_matrix(transmatrix T) {
vector<ld> ver;
for(int i=0; i<3; i++)
for(int j=0; j<3; j++) {
ld a = T[0][i] * T[0][j] + T[1][i]*T[1][j] - T[2][i] * T[2][j];
ver.push_back(kz(a));
}
println(hlog, ver);
}
ld move_dist;
void set_view() {
move_dist = hdist0(currentmap->adj(cwt.at, 0) * C0);
if(in_h2xe() && PURE && S3 == 4) {
ld dist = PIU(hdist0(get_corner_position(currentmap->gamestart(), 0)));
dist -= 1e-4;
move_dist = PIU(hdist(get_corner_position(currentmap->gamestart(), 0), get_corner_position(currentmap->gamestart(), 1)));
tView = xpush(-dist) * tView;
tView = spin(135._deg) * tView;
}
if(in_h2xe() && UNRECTIFIED)
tView = spin(135._deg) * tView;
if(in_h2xe() && S7 == 4)
tView = spin90() * tView;
if(in_s2xe())
tView = spin90() * tView;
if(in_e2xe())
tView = spin90() * tView;
}
void set_tview(transmatrix T) {
View = T * tView;
transmatrix rel = pView * inverse(View);
fixmatrix(rel);
centerover = ncenter;
optimizeview();
ncenter = centerover;
// tView = View;
if(bgeom == 4)
tView = spin(72._deg*at.spin);
else
tView = spin(90._deg*at.spin);
if(at.mirrored)
tView = MirrorY * tView;
// tView = spin(90._deg*at.spin);
set_view();
pView = rel * tView;
when_t = ticks + turn_animation;
}
void rotate_block(int d, bool camera_only) {
if(!rotate_allowed && !camera_only) {
playSound(cwt.at, "hit-crush3");
return;
}
if(!camera_only) remove_shape();
cellwalker at1 = flatspin(at, d);
if(camera_only || !shape_conflict(at1)) {
at = at1;
set_tview(spin(d*90._deg));
}
else playSound(cwt.at, "hit-crush3");
if(!camera_only) draw_shape();
}
int nilmap(int dir) {
if(nil) {
int nm[4] = {3, 2, 0, 5};
return nm[dir];
}
if(sol) {
int nm[4] = {11, 10, 5, 4};
return nm[dir];
}
exit(1);
}
cell *shift_block_target(int dir) {
return flatspin(at, dir).cpeek();
}
void shift_block(int dir, bool camera_only) {
int t = currentmap->gamestart()->type;
if(mproduct) t -= 2;
if(!camera_only) remove_shape();
cellwalker at1;
if(solnil) {
at1.at = at.at->cmove(nilmap(dir));
}
else if(t&1) {
if(dir == 3)
at1 = flatspin(flatspin(at, 4) + wstep, 3);
if(dir == 1)
at1 = flatspin(flatspin(at, 2) + wstep, 1);
if(dir == 2)
at1 = flatspin(flatspin(at, 3) + wstep, 4);
if(dir == 0)
at1 = flatspin(flatspin(at, 1) + wstep, 2);
}
else {
int kspin = (t/2) - dir;
at1 = flatspin(at, dir);
at1 = flatspin(at1 + wstep, kspin);
}
ld angle = dir * 90 * degree;
if(camera_only || !shape_conflict(at1)) {
// playSound(cwt.at, "hit-crush1");
at = at1;
if(solnil) {
pView = pView * currentmap->adj(cwt.at, nilmap(dir));
when_t = ticks + turn_animation;
}
else
set_tview(spin(-angle) * ypush(-move_dist) * spin(angle));
if(!camera_only) draw_shape();
}
else playSound(cwt.at, "hit-crush3");
}
void bringris_action(int k) {
if(k < 4) shift_block(k);
if(k == 4) rotate_block(1);
if(k == 5) rotate_block(-1);
if(k == 6) drop();
if(k == 7) fulldrop();
if(k == 8) paused = true;
}
void create_matrices() {
dq::clear_all();
make_actual_view();
dq::enqueue_by_matrix_c(centerover, cview());
current_display->all_drawn_copies.clear();
int id = 0;
while(!dq::drawqueue_c.empty()) {
auto& p = dq::drawqueue_c.front();
cell*& c = p.first;
shiftmatrix& V = p.second;
current_display->all_drawn_copies[c].push_back(V);
gmatrix[p.first] = p.second;
if(id < draw_per_level) {
auto go = [&] (int i) {
cell *c1 = c->cmove(i);
dq::enqueue_by_matrix_c(c1, optimized_shift(V * currentmap->adj(c, i)));
};
if(mproduct) {
for(int i=0; i<c->type-2; i++) go(i);
}
else if(sol) {
go(4); go(5); go(10); go(11);
}
else if(nil) {
go(0); go(2); go(3); go(5);
}
}
dq::drawqueue_c.pop();
id++;
}
}
transmatrix smooth;
void change_depth(shiftmatrix& V, int newlevel, int zlev) {
if(solnil) {
while(newlevel > zlev) zlev++, V = V * currentmap->adj(cwt.at, down_dir());
while(newlevel < zlev) zlev--, V = V * currentmap->adj(cwt.at, up_dir());
}
else if(in_h2xe())
V = shiftless(V.T, cgi.plevel * (newlevel - zlev));
else
V = shiftless(V.T * zpush(cgi.plevel * (newlevel - zlev)));
}
void draw_wirecube_at(cell *c, const transmatrix& rel, int zlev, color_t col) {
auto where_c = get_where(c);
auto c_camera = get_at(where_c.first, zlev);
for(shiftmatrix V: current_display->all_drawn_copies[c_camera]) {
change_depth(V, where_c.second, zlev);
for(int i=0; i<c->type; i++)
queuepolyat(V * rel, cgi.shWireframe3D[i], 0, PPR::SUPERLINE).outline = col;
}
}
void draw_piece(int zlev, int id) {
auto shape = build_from(piecelist[id].code, at);
auto matrices = build_shape_matrices(piecelist[id].code, at);
auto where_at = get_where(at.at);
vid.linewidth *= 3;
int mid = 0;
for(auto c: shape) {
auto where_c = get_where(c.at);
color_t levels[5] = {color_t(0xFFFFFFFFF), color_t(0xFFFF00FF), color_t(0xFF8000FF), color_t(0xFF0000FF), color_t(0xC000C0FF) };
draw_wirecube_at(at.at, smooth * matrices[mid++], zlev, levels[where_at.second-where_c.second]);
}
vid.linewidth /= 3;
}
void draw_holes(int zlev) {
bool d = state == tsFalling && shape_drawn();
if(d) remove_shape();
for(auto lev: level) {
bool covered = false;
for(int z=well_size; z>=1; z--) {
cell *c1 = get_at(lev, -z);
if(c1->wall) covered = true;
else if(covered) {
vid.linewidth *= 4;
draw_wirecube_at(c1, Id, zlev, (get_hipso(z) << 8) | 0xFF);
vid.linewidth /= 4;
}
}
}
if(d) draw_shape();
}
void draw_all_noray(int zlev) {
for(auto lev: level) {
for(int z=0; z<=camera_level+1; z++) {
cell *c1 = get_at(lev, -z);
if(c1->wall) {
auto c_camera = get_at(lev, zlev);
for(shiftmatrix V: current_display->all_drawn_copies[c_camera]) {
change_depth(V, -z, zlev);
color_t wcol = c1->landparam;
if(c1->wall == waBarrier) wcol = winf[waBarrier].color;
int d = (wcol & 0xF0F0F0) >> 4;
forCellIdCM(c2, i, c1)
if(!c2->wall) {
color_t col = darkena(wcol - d * get_darkval(c1, i), 0, 0xFF);
auto &q = queuepolyat(V, cgi.shWall3D[i], col, PPR::WALL);
q.tinf = &floor_texture_vertices[cgi.shFloor.id];
ensure_vertex_number(*q.tinf, q.cnt);
}
}
}
}
}
}
void start_new_game();
bool use_equidistant;
void bringris_frame() {
if(!in_bringris) return;
ray::want_use = use_raycaster ? 2 : 0;
#if CAP_VR
vrhr::hsm = explore ? vrhr::eHeadset::holonomy : vrhr::eHeadset::reference;
vrhr::eyes = use_equidistant ? vrhr::eEyes::equidistant : vrhr::eEyes::truesim;
#endif
int zlev = get_z(centerover);
if(state == tsCollect) for(cell *c: to_disappear) c->landparam = flashes ? rand() & 0xFFFFFF : 0x101010;
// just_gmatrix = true;
create_matrices();
if(!use_raycaster)
draw_all_noray(zlev);
if(anyshiftclick) draw_holes(zlev);
if(state == tsFalling && !explore && !cur_ang) draw_piece(zlev, shape_id);
}
renderbuffer *next_buffer;
void draw_screen(int xstart, bool show_next) {
int steps = camera_level - (-get_z(at.at));
if(state != tsFalling) steps = camera_level - (well_size + 1);
#if CAP_VR
if(!explore) {
E4;
vrhr::hmd_at_ui = vrhr::hmd_ref_at * cspin(0, 2, 30._deg);
}
#endif
dynamicval<display_data> ccd(*current_display);
current_display->xmax = xstart * 1. / vid.xres;
ray::max_cells = (isize(level) + isize(out_level)) * (camera_level+2);
if(explore) {
gamescreen();
lps_enable(&lps_bringris_explore);
}
else {
lps_enable(&lps_bringris_play);
NLP = Id;
View = pView;
if(nil) {
centerover = at.at;
rotate_view(cspin90(2, 1));
shift_view(ztangent(3 * nilv::nilwidth));
rotate_view(cspin90(1, 0));
anims::moved();
}
else if(sol) {
centerover = at.at;
rotate_view(cspin180(1, 2));
shift_view(ztangent(1));
rotate_view(cspin90(1, 0));
anims::moved();
}
else {
ld lv = -cgi.plevel * steps;
shift_view(ztangent(lv));
rotate_view(cspin(1, 2, cur_ang));
shift_view(ztangent(cgi.plevel * (2 + max_piece)));
centerover = ncenter;
anims::moved();
}
// make_actual_view();
// anims::moved();
sightranges[geometry] *= 100;
if(state == tsFalling && !explore && !cur_ang && !lctrlclick) remove_shape();
gamescreen();
if(state == tsFalling && !explore && !cur_ang) draw_shape();
extern void render_next(int xstart);
render_next(xstart);
sightranges[geometry] /= 100;
if(state == tsBetween) state_loop();
if(state == tsCollect && ticks >= move_at)
disappear_lines();
if(ticks >= move_at && state == tsFalling && pro_game) {
drop();
}
View = pView;
centerover = ncenter;
NLP = Id;
}
}
void create_game();
void geometry_menu() {
clearMessages();
dialog::init("Bringris geometries");
dialog::addBreak(100);
for(int i=0; i<isize(bgeoms); i++) {
dialog::addTitle(bgeoms[i].name, i == bgeom ? 0xFF00 : 0xFF0000, 150);
dialog::items.back().key = 'a' + i;
dialog::add_action([i] {
enable_bgeom(i);
});
dialog::addInfo(bgeoms[i].cap);
dialog::items.back().key = 'a' + i;
dialog::addBreak(50);
if(i == bgeom) bgeoms[i].flags &= ~SECRET;
if(bgeoms[i].flags & SECRET) {
dialog::items.pop_back();
dialog::items.pop_back();
dialog::items.pop_back();
}
}
dialog::addBreak(100);
dialog::addSelItem("max piece", its(max_piece), 'M');
dialog::add_action([] {
max_piece++;
if(max_piece == 6) max_piece = 2;
create_game();
state = tsPreGame;
});
if(bflags() & ASYMMETRIC_ONLY)
dialog::addInfo("(only asymmetric large pieces)");
else if(bflags() & FLAT_ONLY)
dialog::addInfo("(only flat pieces)");
else
dialog::addBreak(100);
dialog::addBreak(100);
dialog::addBack();
dialog::display();
}
void visual_menu() {
cmode = sm::MAYDARK;
gamescreen();
dialog::init("Bringris visuals");
dialog::addBoolItem_action("flashes on level completed", flashes, 'f');
dialog::addBoolItem_action("use raycasting", use_raycaster, 'r');
dialog::addSelItem(XLAT("iterations in raycasting"), its(ray::max_iter_current()), 's');
dialog::add_action([&] {
dialog::editNumber(ray::max_iter_current(), 0, 600, 1, 60, XLAT("iterations in raycasting"), "");
dialog::reaction = ray::reset_raycaster;
});
dialog::addSelItem(XLAT("reflective walls in raycasting"), fts(ray::reflect_val), 'R');
dialog::add_action([&] {
dialog::editNumber(ray::reflect_val, 0, 1, 0.1, 0, XLAT("reflective walls"), "");
dialog::reaction = ray::reset_raycaster;
});
dialog::addSelItem(XLAT("cells to draw per level"), its(draw_per_level), 'R');
dialog::add_action([&] {
dialog::editNumber(draw_per_level, 0, 1000, 500, 50, XLAT("cells to draw"),
"If the level size is 30, 600 cells to draw means that every cell is drawn 20 times on average. "
"Used when raycasting is off, and to draw the wireframes");
});
dialog::addBreak(200);
#if CAP_VR
dialog::addBoolItem_action(XLAT("VR enabled"), vrhr::enabled, 'o');
if(!vrhr::enabled)
dialog::addBreak(100);
else if(vrhr::failed)
dialog::addInfo(XLAT("error: ") + vrhr::error_msg, 0xC00000);
else
dialog::addInfo(XLAT("VR initialized correctly"), 0x00C000);
if(vrhr::active()) {
dialog::addBoolItem_action(XLAT("equidistant VR"), use_equidistant, 'e');
if(use_equidistant)
dialog::addInfo("(distances are seen correctly)");
else
dialog::addInfo("(simulate non-Euclidean binocular vision)");
add_edit(vrhr::cscr);
}
else
dialog::addBreak(300);
#endif
dialog::addBreak(100);
dialog::addBack();
dialog::display();
}
void settings_menu() {
emptyscreen();
dialog::init("Bringris settings");
dialog::addItem("alternative geometry", 'g');
dialog::add_action_push(geometry_menu);
dialog::addItem("visuals & Virtual Reality", 'v');
dialog::add_action_push(visual_menu);
dialog::addItem("configure keys", 'k');
dialog::add_action_push(multi::get_key_configurer(1, move_names, "Bringris keys", scfg_bringris));
#if CAP_AUDIO
add_edit(effvolume);
if(music_available) add_edit(musicvolume);
#endif
dialog::addBreak(100);
#if CAP_FILES && !ISWEB
dialog::addItem("save the current config", 's');
dialog::add_action([] {
dynamicval<eGeometry> g(geometry, gNormal);
saveConfig();
});
#endif
dialog::addBack();
dialog::display();
}
void adjust_animation(ld part) {
if(solnil) {
hyperpoint sh = pView * C0;
sh = lerp(C0, sh, 1-part);
pView = eupush(sh);
smooth = inverse(pView);
}
else {
transmatrix T = pView * inverse(tView);
hyperpoint vec = inverse_exp(shiftless(tC0(T)));
transmatrix Tspin = gpushxto0(tC0(T)) * T;
ld alpha = atan2(Tspin*xpush0(1));
println(hlog, "vec=", vec, " part = ", part);
pView = spin(alpha * part) * gpushxto0(direct_exp(vec*part)) * pView;
fixmatrix(pView);
View = tView;
smooth = inverse(pView) * cview().T;
}
}
bool next_fail = false;
int TEXTURESIZE = 256;
int nxmin, nxmax, nymin, nymax;
void render_next(int xstart) {
if(!next_buffer && !next_fail) {
next_buffer = new renderbuffer(TEXTURESIZE, TEXTURESIZE, true);
if(!next_buffer->valid) {
next_fail = true;
delete next_buffer;
next_buffer = nullptr;
println(hlog, "failed to create next_buffer");
}
else println(hlog, "valid next_buffer created");
}
nxmin = (xstart + vid.fsize);
nxmax = (vid.xres - vid.fsize);
nymin = vid.yres - (vid.fsize * (18+8));
nymax = vid.yres - (vid.fsize * 18);
int zlev = get_z(centerover);
if(!next_buffer) {
if(1) {
dynamicval<display_data> ccd(*current_display);
current_display->xmin = nxmin * 1. / vid.xres;
current_display->xmax = nxmax * 1. / vid.xres;
current_display->ymin = 1 - nymax * 1. / vid.yres;
current_display->ymax = 1 - nymin * 1. / vid.yres;
calcparam();
initquickqueue();
draw_piece(zlev, next_shape_id);
quickqueue();
}
calcparam();
return;
}
if(1) {
resetbuffer rb;
next_buffer->enable();
dynamicval<int> dx(vid.xres, TEXTURESIZE);
dynamicval<int> dy(vid.yres, TEXTURESIZE);
dynamicval<ld> dxmi(current_display->xmin, 0);
dynamicval<ld> dxma(current_display->xmax, 1);
dynamicval<ld> dymi(current_display->ymin, 0);
dynamicval<ld> dyma(current_display->ymax, 1);
#if CAP_VR
dynamicval<int> dvr(vrhr::state, 0);
#endif
calcparam();
current_display->set_viewport(0);
setGLProjection();
// gamescreen(1);
initquickqueue();
draw_piece(zlev, next_shape_id);
quickqueue();
rb.reset();
}
}
EX void reset_vr_ref() {
#if CAP_VR
vrhr::hmd_ref_at = vrhr::hmd_at_ui = vrhr::hmd_at;
#endif
}
EX void display_next(int xstart) {
if(next_buffer) {
current_display->next_shader_flags = GF_TEXTURE;
dynamicval<eModel> m(pmodel, mdPixel);
current_display->set_all(0, 0);
glBindTexture(GL_TEXTURE_2D, next_buffer->renderedTexture);
glhr::id_modelview();
glhr::set_depthtest(false);
glhr::color2(0xFFFFFFFF);
vector<glhr::textured_vertex> tvx;
for(int a=0; a<6; a++) {
int dx[6] = {0, 1, 1, 0, 0, 1};
int dy[6] = {0, 0, 1, 0, 1, 1};
glhr::textured_vertex tx;
tx.coords[2] = 0;
tx.coords[3] = 1;
tx.coords[0] = (dx[a] ? nxmax : nxmin) - current_display->xcenter;
tx.coords[1] = (dy[a] ? nymax : nymin) - current_display->ycenter;
tx.texture[0] = dx[a];
tx.texture[1] = dy[a];
tvx.push_back(tx);
}
glhr::prepare(tvx);
glDrawArrays(GL_TRIANGLES, 0, 6);
}
}
purehookset bringris_extensions;
void run() {
clearMessages();
dialog::init();
if(ang < cur_ang) {
cur_ang -= (ticks - lti) / 1000.;
if(cur_ang < ang) cur_ang = ang;
}
if(ang > cur_ang) {
cur_ang += (ticks - lti) / 1000.;
if(cur_ang > ang) cur_ang = ang;
}
lti = ticks;
if(explore) ;
else if(ticks > when_t) {
pView = tView;
View = pView;
smooth = Id;
}
else adjust_animation((ticks - last_adjust) * 1. / (when_t - last_adjust));
last_adjust = ticks;
ray::want_use = use_raycaster ? 2 : 0;
sightranges[geometry] = 50;
if(!solnil) vid.cells_drawn_limit = 1;
else vid.cells_drawn_limit = 2000;
cmode = sm::NORMAL | sm::CENTER;
if(!explore) cmode |= sm::VR_MENU;
int xstart = vid.xres;
if(!nohud) xstart -= vid.fsize * 10;
getcstat = '-';
bool show_next = state != tsGameover && state != tsPreGame && !paused;
#if CAP_VR
dynamicval<reaction_t> d(vrhr::change_ui_bounds, [show_next, xstart] {
vrhr::ui_xmin = xstart;
vrhr::ui_xmax = vid.xres;
if(show_next && !explore)
vrhr::ui_ymin = vid.yres - vid.fsize * 28;
});
#endif
draw_screen(xstart, show_next);
calcparam();
bool in_menu = !show_next && !explore;
if(nohud) {
describeMouseover();
}
else {
for(int i=0; i<isize(by_level); i++) {
displaystr(xstart + vid.fsize, vid.yres - vid.fsize * (i+2), 0, vid.fsize, its(by_level[i]), get_hipso(i+1), 0);
}
displaystr(xstart + vid.fsize, vid.yres - vid.fsize * 1, 0, vid.fsize, its(isize(level)), winf[waBarrier].color, 0);
if(state != tsPreGame) {
displaystr(xstart + vid.fsize, vid.yres - vid.fsize * 16, 0, vid.fsize, "LEVELS " + its(completed), winf[waBarrier].color, 0);
displaystr(xstart + vid.fsize, vid.yres - vid.fsize * 15, 0, vid.fsize, "BRICKS " + its(bricks), winf[waBarrier].color, 0);
displaystr(xstart + vid.fsize, vid.yres - vid.fsize * 14, 0, vid.fsize, "CUBES " + its(cubes), winf[waBarrier].color, 0);
if(pro_game)
displaystr(xstart + vid.fsize, vid.yres - vid.fsize * 13, 0, vid.fsize, "SCORE " + fts(int(score)), winf[waBarrier].color, 0);
}
if(show_next) {
displaystr(xstart + vid.fsize, vid.yres - vid.fsize * 27, 0, vid.fsize, "NEXT:", winf[waBarrier].color, 0);
#if CAP_VR
if(vrhr::active())
vrhr::in_vr_ui([xstart] {
display_next(xstart);
});
else
#endif
display_next(xstart);
}
if(explore) {
int xx = (xstart + vid.xres) / 2;
if(displayButtonS(xx, vid.fsize * 2, "backspace", 0xFFFFFFFF, 8, vid.fsize)) getcstat = SDLK_BACKSPACE;
if(displayButtonS(xx, vid.fsize * 3, "to stop", 0xFFFFFFFF, 8, vid.fsize)) getcstat = SDLK_BACKSPACE;
if(displayButtonS(xx, vid.fsize * 4, "exploring", 0xFFFFFFFF, 8, vid.fsize)) getcstat = SDLK_BACKSPACE;
}
if(in_menu) {
int xx = (xstart + vid.xres) / 2;
if(paused) {
if(displayButtonS(xx, vid.fsize * 2, "CONTINUE", 0xFFFFFFFF, 8, vid.fsize)) getcstat = 'p';
}
else if(state == tsGameover) {
displayButtonS(xx, vid.fsize * 2, "game over", 0xFFFFFFFF, 8, vid.fsize);
}
if(displayButtonS(xx, vid.fsize * 4, "NEW GAME", 0xFFFFFFFF, 8, vid.fsize)) getcstat = 'n';
if(displayButtonS(xx, vid.fsize * 6, "EXPERT GAME", 0xFFFFFFFF, 8, vid.fsize)) getcstat = 'x';
if(displayButtonS(xx, vid.fsize * 8, "SETTINGS", 0xFFFFFFFF, 8, vid.fsize)) getcstat = 's';
if(state != tsPreGame)
if(displayButtonS(xx, vid.fsize * 10, "EXPLORE", 0xFFFFFFFF, 8, vid.fsize)) getcstat = 'e';
if(!ISWEB) {
if(displayButtonS(xx, vid.fsize * 12, "QUIT", 0xFFFFFFFF, 8, vid.fsize)) getcstat = 'q';
}
else if(state == tsGameover)
if(displayButtonS(xx, vid.fsize * 12, "TWEET", 0xFFFFFFFF, 8, vid.fsize)) getcstat = 't';
if(vrhr::active())
if(displayButtonS(xx, vid.fsize * 14, "RESET VR", 0xFFFFFFFF, 8, vid.fsize)) getcstat = 'V';
}
}
keyhandler = [xstart, in_menu] (int sym, int uni) {
if(explore) handlePanning(sym, uni);
if(explore && sym == SDLK_BACKSPACE)
explore = false;
if(state == tsFalling && !paused) {
multi::handleInput(0, scfg_bringris);
bool consumed = false;
for(int i=0; i<bmLast; i++)
if(multi::actionspressed[16+i] && !multi::lactionpressed[16+i]) {
bringris_action(i);
consumed = true;
}
if(consumed) return;
}
dialog::handleNavigation(sym, uni);
if(in_menu && sym == 'q' && !ISWEB) {
in_bringris = false;
quitmainloop = true;
}
if(sym == '-') {
if(!which_pointer) {
int ax = mousex * 3 / xstart;
if(ax > 3) ax = 3;
int ay = mousey * 3 / vid.yres;
if(ay > 2) ay = 2;
int id = ay * 4 + ax;
eBringrisMove moves[12] = {
bmTurnLeft, bmUp, bmTurnRight, bmPause,
bmLeft, bmDrop, bmRight, bmFullDrop,
bmNothing, bmDown, bmNothing, bmFullDrop
};
eBringrisMove mov = moves[id];
if((state == tsFalling && !paused) || mov == bmPause)
bringris_action(mov);
}
#if CAP_VR
else {
if(explore)
explore = !explore;
else if(
mousex >= vrhr::ui_xmin && mousex <= vrhr::ui_xmax &&
mousey >= vrhr::ui_ymin && mousey <= vrhr::ui_ymax)
paused = !paused;
else {
vrhr::compute_vr_direction(which_pointer);
ld r = 1 / sqrt(2);
auto& dir = vrhr::vr_direction;
vector<pair<eBringrisMove, hyperpoint> > choices = {
{bmLeft, hyperpoint(-1, 0, 0, 0)},
{bmRight, hyperpoint(1, 0, 0, 0)},
{bmUp, hyperpoint(0, -1, 0, 0)},
{bmDown, hyperpoint(0, 1, 0, 0)},
{bmTurnLeft, hyperpoint(-r, -r, 0, 0)},
{bmTurnRight, hyperpoint(r, -r, 0, 0)},
{bmDrop, hyperpoint(-r, r, 0, 0)},
{bmFullDrop, hyperpoint(r, r, 0, 0)}
};
eBringrisMove mov = bmNothing;
ld best = 0;
for(auto& b: choices) {
ld dot = (dir | b.second);
if(dot > best) best = dot, mov = b.first;
}
bringris_action(mov);
}
println(hlog, vrhr::vr_direction);
}
#endif
return;
}
// if(sym == 'k') ang = 0;
// if(sym == 'l') ang = 45 * degree;
if(sym == 'p' || sym == 'c' || (sym == SDLK_ESCAPE && !ISWEB)) {
if(!paused) move_at = move_at - ticks;
paused = !paused;
if(!paused) move_at = move_at - ticks;
explore = false;
}
if(sym == 't' && state == tsGameover) {
const vector<const char*> emoji =
{"😀","😎","👽","🤖","😺","🎩","🎓","👑","💍","🐯","🦁","🐮","🐷","🐽","🐸","🐙","🐵","🐦","🐧","🐔","🐒","🙉","🙈","🐣","🐥","🐺","🐗","🐴","🦄","🐝","🐛","🐢","🦀","🦂","🕷","🐜","🐞","🐌","🐠","🐟","🐡","🐬","🐋","🐊","🐆","🐘","🐫","🐪","🐄","🐂","🐃","🐏","🐑","🐀","🐁","🐓","🦃","🐉","🐾","🐿","🐇","🐈","🐩","🐕","🐲","🌵","🍁","🌻","🌎","⭐️","⚡️","🔥","❄️","☔️","☂️","💧","🍏","🍎","🍐","🍋","🍌","🍉","🍇","🌶","🍅","🍍","🍑","🍈","🍓","🌽","🍠","🍯","🍞","🍗","🧀","🍖","🍤","🌯","🌮","🍝","🍕","🌭","🍟","🍔","⚽️","🎱","🏆","🎪","🎲","🎳","🚗","🚕","🚙","🏎","⛺️","","🕹","💾","☎️","","🔦","💡","💰","💎","🔨","💣","🔑","❤️","🔔"};
string out;
if(pro_game) {
out = "Got " + its(score) + " points for completing " + its(completed) + " levels in #Bringris!";
}
else if(completed) {
out = "Used " + its(bricks) + " blocks to complete " + its(completed) + " levels in #Bringris!";
}
else {
out = "Dropped " + its(bricks) + " blocks in #Bringris!";
}
if(bgeom || max_piece != 4) out += " (" + bgeoms[bgeom].name + "/" + its(max_piece) + ")";
unsigned hash = time(NULL) / 600;
for(char c: out) hash = 171 * hash + c;
std::mt19937 invr;
invr.seed(hash);
out += " ";
for(int i=0; i<4; i++)
out += emoji[invr() % isize(emoji)];
// println(hlog, out);
#if ISWEB
EM_ASM({
var tweetbegin = 'https://twitter.com/intent/tweet?text=';
var tweettxt = UTF8ToString($0, $1);
var finaltweet = tweetbegin +encodeURIComponent(tweettxt) + "&url=https://zenorogue.itch.io/bringris";
window.open(finaltweet,'_blank');
}, out.c_str(), isize(out));
#endif
}
if(in_menu && sym == 'e') {
explore = !explore;
}
if(sym == 'V') {
reset_vr_ref();
}
if(in_menu && sym == 'n') {
start_new_game();
paused = false;
explore = false;
pro_game = false;
playSound(cwt.at, "elementalgem");
}
if(in_menu && sym == 's') {
pushScreen(settings_menu);
}
if(in_menu && sym == 'x') {
start_new_game();
paused = false;
explore = false;
pro_game = true;
playSound(cwt.at, "elementalgem");
}
#if CAP_SHOT
if(sym == ']') {
static int id = 0;
perfect_linewidth = 0;
shot::shot_aa = 2;
vid.linewidth *= 2;
shot::take(hr::format("bringris-%04d.png", id++), [] { draw_screen(vid.xres, false); });
vid.linewidth /= 2;
}
#endif
#ifdef MAKE_VIDEO
if(sym == '[') {
perfect_linewidth = 0;
shot::shot_aa = 4;
vid.linewidth *= 5;
int dir = 3;
int fpm = in_s2xe() ? 60 : 30;
int steps = 0;
auto att = at;
bool boundedw = bflags() & BOUNDED_WELL;
if(boundedw) steps = 20;
else do {
steps++;
shift_block(dir);
}
while(at != att);
println(hlog, steps, " steps of ", fpm, " frames each");
anims::noframes = steps * fpm;
anims::period = steps * fpm;
int lt = -1;
int p = addHook(anims::hooks_anim, 200, [&] {
int t = ticks;
if(t == lt) {
println(hlog, "ignore");
return;
}
lt = t;
println(hlog, "t = ", t);
if(t % fpm == 0) {
pView = tView;
View = pView;
smooth = Id;
shift_block(dir);
if(boundedw) dir = (1+dir) % 4;
}
if(boundedw) {
auto f = [fpm] (ld k) { k /= fpm; return k * k * (3 - 2 * k); };
ld a = f(t % fpm);
ld b = f(t % fpm + 1);
adjust_animation((b-a) / (1-a));
}
else
adjust_animation(1. / (fpm - t % fpm));
});
anims::record_video("bringris.mp4", [] { return anims::record_animation_of( [] { println(hlog, "called"); draw_screen(vid.xres, false); } ); });
delHook(anims::hooks_anim, p);
vid.linewidth /= 5;
}
#endif
};
callhooks(bringris_extensions);
}
cell *get_center() {
return well_center ? well_center : level[0];
}
void reset_view() {
centerover = get_at(get_center(), -camera_level);
cwt.at = centerover;
ncenter = get_at(get_center(), -camera_level);
NLP = Id;
tView = Id;
set_view();
pView = tView;
}
void start_new_game() {
for(auto& p: piecelist) p.count = 0;
for(auto lev: level) for(int z=0; z<=camera_level+1; z++) {
cell *c = get_at(lev, -z);
setdist(c, 7, nullptr);
c->item = itNone;
c->land = laCanvas;
if(z == 0)
c->wall = waBarrier, c->land = laBarrier;
else if(z <= camera_level)
c->wall = waNone;
else
c->wall = waWaxWall, c->land = laCanvas, c->landparam = 0xC000C0;
}
for(auto lev: out_level) for(int z=1; z<=camera_level; z++) {
cell *c = get_at(lev, -z);
c->item = itNone;
c->land = laCanvas;
c->wall = waWaxWall;
c->landparam = (get_hipso(z) & 0xFCFCFC) >> 2;
}
at = get_at(get_center(), -well_size - 1);
next_shape_id = choose_piece();
state = tsBetween;
reset_view();
ray::reset_raycaster_map();
// reset_view();
completed = 0;
bricks = 0;
cubes = 0;
score = 0;
}
void get_level() {
if(bflags() & BOUNDED_WELL) {
set<cell*> all;
well_center = currentmap->gamestart();
all.insert(well_center);
for(int i=0; i<4; i++)
for(int l: {-1, 0, 1})
for(int j=0; j<4; j++)
for(int k: {-1, 1}) {
cellwalker cw(well_center, i);
cw += wstep;
all.insert(cw.at);
if(l) {
cw += l;
cw += wstep;
all.insert(cw.at);
}
cw += j;
cw += wstep;
all.insert(cw.at);
cw += k;
cw += wstep;
all.insert(cw.at);
}
set<cell*> all_ext;
for(cell *c: all)
forCellCM(d, c)
if(!all.count(d))
all_ext.insert(d);
level.clear();
for(auto c: all)
level.push_back(c);
for(auto c: all_ext)
out_level.push_back(c);
}
else {
level = currentmap->allcells();
if(bflags() & ORBIFOLD) {
vector<cell*> clist;
set<cell*> visited;
auto visit = [&] (cell *c) {
if(!visited.count(c))
visited.insert(c),
clist.push_back(c);
};
for(auto c: level) if(isNeighbor(c, c)) visit(c);
for(int i=0; i<isize(clist); i++)
for(int j=0; j<clist[i]->type; j++)
visit(clist[i]->cmove(j));
well_center = clist.back();
}
}
if(well_center) {
vector<cell*> visited;
set<cell*> all;
for(auto l: level) all.insert(l);
auto visit = [&] (cell *c, int d) {
if(all.count(c) && !center_distance.count(c))
center_distance[c] = d,
visited.push_back(c);
};
visit(well_center, 0);
for(int i=0; i<isize(visited); i++)
for(int j=0; j<visited[i]->type; j++)
visit(visited[i]->move(j), center_distance[visited[i]] + 1);
}
}
void create_game() {
level.clear();
out_level.clear();
well_center = nullptr;
if(!mproduct && !solnil) {
println(hlog, "need product or Solnil geometry");
exit(1);
}
if(nil) {
for(int x=0; x<5; x++)
for(int y=0; y<5; y++)
level.push_back(nilv::get_heptagon_at(nilv::mvec(x, 0, y))->c7);
}
else if(sol) {
level.clear();
for(int x=0; x<5; x++)
for(int y=0; y<5; y++)
level.push_back(asonov::get_at(asonov::coord(x, y, 0))->c7);
}
else
PIU(get_level());
piecelist.clear();
piecelist.reserve(2000);
seen_blocks.clear();
for(int ps=1; ps<=max_piece; ps++)
generate_shapes(ps);
list_all();
// println(hlog, "level size = ", isize(level));
camera_level = well_size + max_piece + camera;
playermoved = false;
ray::max_iter_current() = solnil ? 600 : 200;
start_new_game();
state = tsPreGame;
}
void init_all() {
lps_enable(&lps_bringris);
enable_bgeom();
vid.texture_step = 8;
showstartmenu = false;
pushScreen(run);
in_bringris = true;
}
int args() {
using namespace arg;
if(0) ;
else if(argis("-list")) {
PHASEFROM(3);
start_game();
shift(); int i = argi();
generate_shapes(i);
list_all();
}
else if(argis("-bringris0")) {
PHASEFROM(3);
start_game();
create_game();
}
else if(argis("-bgeo")) {
PHASEFROM(2);
shift();
enable_bgeom(argi());
}
else if(argis("-bringris")) {
PHASEFROM(2);
init_all();
}
else if(argis("-ray-off"))
use_raycaster = false;
else if(argis("-ray-on"))
use_raycaster = true;
else if(argis("-dpl")) {
shift(); draw_per_level = argi();
}
else return 1;
return 0;
}
void change_default_key(int key, int val) {
char* t = scfg_bringris.keyaction;
t[key] = val;
}
void default_config() {
clear_config(scfg_bringris);
change_default_key('s', 16 + 0);
change_default_key('a', 16 + 1);
change_default_key('w', 16 + 2);
change_default_key('d', 16 + 3);
change_default_key('q', 16 + 4);
change_default_key('e', 16 + 5);
change_default_key(' ', 16 + 6);
change_default_key('\r',16 + 7);
change_default_key('p', 16 + 8);
sconfig_savers(scfg_bringris, "bringris");
param_i(bgeom, "bringris-geometry", 0);
lps_add(lps_bringris, ray::want_use, ray::want_use);
#if CAP_VR
lps_add(lps_bringris, vrhr::hsm, vrhr::hsm);
lps_add(lps_bringris, vrhr::eyes, vrhr::eyes);
#endif
lps_add(lps_bringris, ray::exp_decay_poly, 200);
lps_add(lps_bringris, ray::fixed_map, true);
lps_add(lps_bringris, mapeditor::drawplayer, false);
lps_add(lps_bringris, vid.fov, 90);
lps_add(lps_bringris, vid.plevel_factor, 0.5);
lps_add(lps_bringris, vid.axes3, false);
lps_add(lps_bringris_explore, mouseaim_sensitivity, 0.01);
lps_add(lps_bringris_explore, camera_speed, 2);
lps_add(lps_bringris_explore, smooth_scrolling, true);
lps_add(lps_bringris_play, mouseaim_sensitivity, 0);
param_b(use_raycaster, "bringris-ray");
param_i(draw_per_level, "draw-per-level");
param_b(use_equidistant, "bringris-equidistant");
param_b(flashes, "bringris-flashes");
}
auto hooks =
addHook(hooks_args, 100, args)
+ addHook(hooks_frame, 100, bringris_frame)
+ addHook(hooks_configfile, 300, default_config)
+ addHook(dialog::hooks_display_dialog, 100, [] () {
if(dialog::items[0].body == "Bringris keys") {
dialog::addBreak(200);
if(!rotate_allowed)
dialog::addHelp("note: rotation keys only available when necessary");
dialog::addHelp("press SHIFT to highlight the holes");
dialog::addHelp("mouse control by pressing parts of the game screen");
}
});
#ifdef BRINGRIS
auto hook1=
addHook(hooks_config, 100, [] {
if(arg::curphase == 1)
conffile = "bringris.ini";
if(arg::curphase == 2) init_all();
});
#endif
}
}