/* Copyright (c) 2012-2015 Stanislaw Halik * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. */ /* * this file appeared originally in facetracknoir, was rewritten completely * following opentrack fork. * * originally written by Wim Vriend. */ #include "compat/sleep.hpp" #include "compat/math.hpp" #include "compat/meta.hpp" #include "pipeline.hpp" #include #include #include #ifdef _WIN32 # include #endif using namespace euler; using namespace time_units; using namespace gui_tracker_impl; static constexpr inline double r2d = 180. / M_PI; static constexpr inline double d2r = M_PI / 180.; reltrans::reltrans() {} euler_t reltrans::rotate(const rmat& R, const euler_t& in, vec3_bool disable) const { enum { tb_Z, tb_X, tb_Y }; // TY is really yaw axis. need swapping accordingly. // sign changes are due to right-vs-left handedness of coordinate system used const euler_t ret = R * euler_t(in(TZ), -in(TX), -in(TY)); euler_t output; if (disable(TZ)) output(TZ) = in(TZ); else output(TZ) = ret(tb_Z); if (disable(TY)) output(TY) = in(TY); else output(TY) = -ret(tb_Y); if (disable(TX)) output(TX) = in(TX); else output(TX) = -ret(tb_X); return output; } Pose reltrans::apply_pipeline(reltrans_state state, const Pose& value, const vec6_bool& disable) { if (state != reltrans_disabled) { euler_t rel { &value[0] }; { bool tcomp_in_zone_ = progn( if (state == reltrans_non_center) { const bool yaw_in_zone = std::fabs(value(Yaw)) < 50; const bool pitch_in_zone = std::fabs(value(Pitch)) < 40; return !(yaw_in_zone && pitch_in_zone); } else return true; ); if (!cur && in_zone != tcomp_in_zone_) { //qDebug() << "reltrans-interp: START" << tcomp_in_zone_; cur = true; interp_timer.start(); } in_zone = tcomp_in_zone_; } // only when looking behind or downward if (in_zone) { const rmat R = euler_to_rmat(euler_t(value(Yaw) * d2r * !disable(Yaw), value(Pitch) * d2r * !disable(Pitch), value(Roll) * d2r * !disable(Roll))); rel = rotate(R, rel, &disable[TX]); } if (cur) { const double dt = interp_timer.elapsed_seconds(); interp_timer.start(); constexpr double RC = .1; const double alpha = dt/(dt+RC); constexpr double eps = .05; interp_pos = interp_pos * (1-alpha) + rel * alpha; const euler_t tmp = rel - interp_pos; rel = interp_pos; const double delta = std::fabs(tmp(0)) + std::fabs(tmp(0)) + std::fabs(tmp(0)); //qDebug() << "reltrans-interp: delta" << delta; if (delta < eps) { //qDebug() << "reltrans-interp: STOP"; cur = false; } } else { interp_pos = rel; } return { rel(0), rel(1), rel(2), value(Yaw), value(Pitch), value(Roll) }; } else { cur = false; in_zone = false; return value; } } euler_t reltrans::apply_neck(const Pose& value, bool enable, int nz) const { if (!enable) return {}; euler_t neck; if (nz != 0) { const rmat R = euler_to_rmat(euler_t(&value[Yaw]) * d2r); neck = rotate(R, { 0, 0, nz }, vec3_bool()); neck(TZ) = neck(TZ) - nz; } return neck; } pipeline::pipeline(Mappings& m, runtime_libraries& libs, event_handler& ev, TrackLogger& logger) : m(m), ev(ev), libs(libs), logger(logger) { } pipeline::~pipeline() { requestInterruption(); wait(); } double pipeline::map(double pos, Map& axis) { bool altp = (pos < 0) && axis.opts.altp; axis.spline_main.set_tracking_active( !altp ); axis.spline_alt.set_tracking_active( altp ); auto& fc = altp ? axis.spline_alt : axis.spline_main; return double(fc.get_value(pos)); } template static bool is_nan(const dmat& r) { for (int i = 0; i < u; i++) for (int j = 0; j < w; j++) { int val = std::fpclassify(r(i, j)); if (val == FP_NAN || val == FP_INFINITE) return true; } return false; } template static force_inline bool nan_check_(const x& datum, const y& next, const xs&... rest) { return is_nan(datum) || nan_check_(next, rest...); } template static force_inline bool nan_check_(const x& datum) { return is_nan(datum); } template static bool nan_check_() = delete; static never_inline void emit_nan_check_msg(const char* text, const char* fun, int line) { once_only( qDebug() << "nan check failed" << "for:" << text << "function:" << fun << "line:" << line; ); } template static never_inline bool maybe_nan(const char* text, const char* fun, int line, const xs&... vals) { if (nan_check_(vals...)) { emit_nan_check_msg(text, fun, line); return true; } return false; } #if defined _MSC_VER # define OTR_FUNNAME2 (__FUNCSIG__) #else # define OTR_FUNNAME2 (__PRETTY_FUNCTION__) #endif // don't expand # define OTR_FUNNAME (OTR_FUNNAME2) #define nan_check(...) \ do \ { \ if (maybe_nan(#__VA_ARGS__, OTR_FUNNAME, __LINE__, __VA_ARGS__)) \ goto nan; \ } while (false) void pipeline::maybe_enable_center_on_tracking_started() { if (!tracking_started) { for (int i = 0; i < 6; i++) if (std::fabs(newpose(i)) != 0) { tracking_started = true; break; } if (tracking_started && s.center_at_startup) set(f_center, true); } } void pipeline::maybe_set_center_pose(const Pose& value, bool own_center_logic) { euler_t tmp = d2r * euler_t(&value[Yaw]); scaled_rotation.rotation = euler_to_rmat(c_div * tmp); real_rotation.rotation = euler_to_rmat(tmp); if (get(f_center)) { if (libs.pFilter) libs.pFilter->center(); if (own_center_logic) { scaled_rotation.rot_center = rmat::eye(); real_rotation.rot_center = rmat::eye(); t_center = euler_t(); } else { real_rotation.rot_center = real_rotation.rotation.t(); scaled_rotation.rot_center = scaled_rotation.rotation.t(); t_center = euler_t(static_cast(value)); } } } Pose pipeline::clamp_value(Pose value) const { // hatire, udp, and freepie trackers can mess up here for (unsigned i = 3; i < 6; i++) { using std::fmod; using std::copysign; using std::fabs; value(i) = fmod(value(i), 360); const double x = value(i); if (fabs(x) - 1e-2 > 180) value(i) = fmod(x + copysign(180, x), 360) - copysign(180, x); else value(i) = clamp(x, -180, 180); } return value; } Pose pipeline::apply_center(Pose value) const { rmat rotation = scaled_rotation.rotation * scaled_rotation.rot_center; euler_t pos = euler_t(value) - t_center; euler_t rot = r2d * c_mult * rmat_to_euler(rotation); pos = rel.rotate(real_rotation.rot_center, pos, vec3_bool()); for (int i = 0; i < 3; i++) { // don't invert after t_compensate // inverting here doesn't break centering if (m(i+3).opts.invert) rot(i) = -rot(i); if (m(i).opts.invert) pos(i) = -pos(i); } for (int i = 0; i < 3; i++) { value(i) = pos(i); value(i+3) = rot(i); } return value; } std::tuple pipeline::get_selected_axis_value(const Pose& newpose) const { Pose value; vec6_bool disabled; for (int i = 0; i < 6; i++) { const Map& axis = m(i); const int k = axis.opts.src; disabled(i) = k == 6; if (k < 0 || k >= 6) value(i) = 0; else value(i) = newpose(k); } return { newpose, value, disabled }; } Pose pipeline::maybe_apply_filter(const Pose& value) const { Pose tmp(value); // nan/inf values will corrupt filter internal state if (libs.pFilter) libs.pFilter->filter(value, tmp); return tmp; } Pose pipeline::apply_zero_pos(Pose value) const { // custom zero position for (int i = 0; i < 6; i++) value(i) += m(i).opts.zero * (m(i).opts.invert ? -1 : 1); return value; } Pose pipeline::apply_reltrans(Pose value, vec6_bool disabled) { const euler_t neck = rel.apply_neck(value, s.neck_enable, -s.neck_z); value = rel.apply_pipeline(s.reltrans_mode, value, { !!s.reltrans_disable_src_yaw, !!s.reltrans_disable_src_pitch, !!s.reltrans_disable_src_roll, !!s.reltrans_disable_tx, !!s.reltrans_disable_ty, !!s.reltrans_disable_tz }); for (int i = 0; i < 3; i++) value(i) += neck(i); // reltrans will move it for (unsigned k = 0; k < 6; k++) if (disabled(k)) value(k) = 0; return value; } void pipeline::logic() { using namespace euler; using EV = event_handler::event_ordinal; logger.write_dt(); logger.reset_dt(); // we must center prior to getting data from the tracker const bool center_ordered = get(f_center) && tracking_started; const bool own_center_logic = center_ordered && libs.pTracker->center(); Pose value, raw; vec6_bool disabled; { Pose tmp; libs.pTracker->data(tmp); nan_check(tmp); ev.run_events(EV::ev_raw, tmp); if (get(f_enabled_p) ^ !get(f_enabled_h)) for (int i = 0; i < 6; i++) newpose(i) = tmp(i); } std::tie(raw, value, disabled) = get_selected_axis_value(newpose); logger.write_pose(raw); // raw value = clamp_value(value); { maybe_enable_center_on_tracking_started(); maybe_set_center_pose(value, own_center_logic); value = apply_center(value); logger.write_pose(value); // "corrected" - after various transformations to account for camera position } { ev.run_events(EV::ev_before_filter, value); value = maybe_apply_filter(value); nan_check(value); logger.write_pose(value); // "filtered" } { ev.run_events(EV::ev_before_mapping, value); // CAVEAT rotation only, due to tcomp for (int i = 3; i < 6; i++) value(i) = map(value(i), m(i)); } value = apply_reltrans(value, disabled); { // CAVEAT translation only, due to tcomp for (int i = 0; i < 3; i++) value(i) = map(value(i), m(i)); nan_check(value); } goto ok; nan: { QMutexLocker foo(&mtx); value = output_pose; raw = raw_6dof; // for widget last value display for (int i = 0; i < 6; i++) (void)map(raw_6dof(i), m(i)); } ok: set(f_center, false); if (get(f_zero)) for (int i = 0; i < 6; i++) value(i) = 0; value = apply_zero_pos(value); ev.run_events(EV::ev_finished, value); libs.pProtocol->pose(value); QMutexLocker foo(&mtx); output_pose = value; raw_6dof = raw; logger.write_pose(value); // "mapped" logger.reset_dt(); logger.next_line(); } void pipeline::run() { #if defined _WIN32 const MMRESULT mmres = timeBeginPeriod(1); #endif { static const char* const posechannels[6] = { "TX", "TY", "TZ", "Yaw", "Pitch", "Roll" }; static const char* const datachannels[5] = { "dt", "raw", "corrected", "filtered", "mapped" }; logger.write(datachannels[0]); char buffer[128]; for (unsigned j = 1; j < 5; ++j) { for (unsigned i = 0; i < 6; ++i) { std::sprintf(buffer, "%s%s", datachannels[j], posechannels[i]); logger.write(buffer); } } logger.next_line(); } logger.reset_dt(); t.start(); while (!isInterruptionRequested()) { logic(); constexpr ns const_sleep_ms(time_cast(ms(4))); const ns elapsed_nsecs = prog1(t.elapsed(), t.start()); if (backlog_time > secs_(3) || backlog_time < secs_(-3)) { qDebug() << "tracker: backlog interval overflow" << time_cast(backlog_time).count() << "ms"; backlog_time = backlog_time.zero(); } backlog_time += ns(elapsed_nsecs - const_sleep_ms); const int sleep_time_ms = time_cast(clamp(const_sleep_ms - backlog_time, ms::zero(), ms(10))).count(); #if 0 qDebug() << "sleepy time" << sleep_time_ms << "elapsed" << time_cast(elapsed_nsecs).count() << "backlog" << time_cast(backlog_time).count(); #endif portable::sleep(sleep_time_ms); } // filter may inhibit exact origin Pose p; libs.pProtocol->pose(p); for (int i = 0; i < 6; i++) { m(i).spline_main.set_tracking_active(false); m(i).spline_alt.set_tracking_active(false); } #if defined _WIN32 if (mmres == 0) (void) timeEndPeriod(1); #endif } void pipeline::raw_and_mapped_pose(double* mapped, double* raw) const { QMutexLocker foo(&const_cast(*this).mtx); for (int i = 0; i < 6; i++) { raw[i] = raw_6dof(i); mapped[i] = output_pose(i); } } void pipeline::set_center() { set(f_center, true); } void pipeline::set_enabled(bool value) { set(f_enabled_h, value); } void pipeline::set_zero(bool value) { set(f_zero, value); } void pipeline::toggle_zero() { negate(f_zero); } void pipeline::toggle_enabled() { negate(f_enabled_p); } void bits::set(flags flag_, bool val_) { const unsigned flag = unsigned(flag_); const unsigned val = unsigned(val_); for (;;) { unsigned b_(b); if (b.compare_exchange_weak(b_, unsigned((b_ & ~flag) | (flag * val)), std::memory_order_seq_cst, std::memory_order_seq_cst)) break; } } void bits::negate(flags flag_) { const unsigned flag = unsigned(flag_); for (;;) { unsigned b_(b); if (b.compare_exchange_weak(b_, b_ ^ flag, std::memory_order_seq_cst, std::memory_order_seq_cst)) break; } } bool bits::get(flags flag) { return !!(b & flag); } bits::bits() : b(0u) { set(f_center, true); set(f_enabled_p, true); set(f_enabled_h, true); set(f_zero, false); }