#define MICHLIB_NOSOURCE #include "AVISOLOCAL.h" MString AVISOLOCALData::Info() const { if(!isOk()) return ""; NCFileA nc; struct CoordNames cn, dn; std::set vars; nc.Reset(datapath + "/uv-" + times[0].ToString() + ".nc"); if(!nc) return "Can't open file " + datapath + "/uv-" + times[0].ToString() + ".nc"; GetVars(nc, vars); dn = GetDNames(nc); cn = GetCNames(nc); MString svars; { bool first = true; for(const auto& v: vars) { svars += (first ? "" : ", ") + v; first = false; } } auto lons = nc.VR(cn.lonname); auto lats = nc.VR(cn.latname); if(!(lons && lats)) return "Can't get longitudes/latitudes"; real lonb = lons(0); real latb = lats(0); real lone = lons(dn.nx - 1); real late = lats(dn.ny - 1); real lonstep = (lone - lonb) / (dn.nx - 1); real latstep = (late - latb) / (dn.ny - 1); // clang-format off return "Dataset: " + DataTitle() + "\n" + " Begin date: " + Time(0).ToString() + "\n" + " End date: " + Time(NTimes()-1).ToString() + "\n" + " Time step: " + Timestep() + " seconds\n" + " Time moments: " + NTimes() + "\n" + " Region: (" + lonb + " : " + lone + ") x (" + latb + " : " + late + ")\n" + " Grid: " + dn.nx + "x" + dn.ny + " (" + lonstep + " x " + latstep + ")\n" + " Supported variables: " + svars; // clang-format on } MString AVISOLOCALData::Open(const CLArgs& args) { GPL.UsePrefix("AVISOLOCAL"); datapath = GPL.ParameterSValue("Datapath", ""); RegExp regex("uv-([0-9]{4}-[0-9]{2}-[0-9]{2}).nc"); regex.Compile(); DIR* dir = opendir(datapath.Buf()); struct dirent* de; if(nullptr == dir) return "Can't open directory " + datapath; while((de = readdir(dir))) { if(!regex.Match(de->d_name)) continue; times.emplace_back(MString(de->d_name + regex.Off(1), regex.Len(1))); } closedir(dir); std::sort(times.begin(), times.end()); return ""; } std::pair AVISOLOCALData::Parameters(michlib_internal::ParameterListEx& pars, const CLArgs& args, const struct Region& reg) const { std::unique_ptr ppar{new struct Parameters}; ppar->lonb = reg.lonb; ppar->lone = reg.lone; ppar->latb = reg.latb; ppar->late = reg.late; pars.SetParameter("lonb", ppar->lonb); pars.SetParameter("latb", ppar->latb); pars.SetParameter("lone", ppar->lone); pars.SetParameter("late", ppar->late); return {ppar.release(), ""}; } AVISOLOCALData::Data AVISOLOCALData::Read(const MString& vname, const BaseParameters* ip, size_t i) const { if(!isOk()) return Data(); auto p = dynamic_cast(ip); NCFileA nc; MString name = ""; bool isfloat = false, isint2 = false, isint4 = false; nc.Reset(datapath + "/uv-" + times[i].ToString() + ".nc"); if(!nc) return Data(); { auto head = nc.Header(); for(const auto& v: head.Variables()) { auto stname = nc.A(v.Name(), "standard_name"); if(!stname) continue; if(StName2Name(stname) == vname) { name = v.Name(); isint2 = v.Type().Id() == NC_SHORT; isint4 = v.Type().Id() == NC_INT; isfloat = v.Type().Id() == NC_FLOAT; } } } if(!name.Exist()) // Conversion read { // U and U2 from u and v if(vname == "U" || vname == "U2") { bool square = vname == "U2"; auto u = Read("u", ip, i); auto v = Read("v", ip, i); if(!(u && v)) return Data(); if(square && u.Unit().Exist()) u.SetUnit("(" + u.Unit() + ")2"); for(size_t ind = 0; ind < u.N(); ind++) { if(u.IsFill(ind) || v.IsFill(ind)) u.V(ind) = u.Fillval(); else u.V(ind) = square ? (u(ind) * u(ind) + v(ind) * v(ind)) : michlib::Hypot(u(ind), v(ind)); } return u; } return Data(); } // Direct read if(isint2) return ReadVarRaw(nc, name, p); if(isint4) return ReadVarRaw(nc, name, p); if(isfloat) return ReadVarRaw(nc, name, p); return Data(); } template AVISOLOCALData::Data AVISOLOCALData::ReadVarRaw(const NCFileA& nc, const MString& name, const struct AVISOLOCALData::Parameters* p) const { real unitmul = 1.0; DataType fill; real offset = 0.0, scale = 1.0; { auto a_fill = nc.A(name, "_FillValue"); auto a_offset_d = nc.A(name, "add_offset"); auto a_scale_d = nc.A(name, "scale_factor"); auto a_offset_f = nc.A(name, "add_offset"); auto a_scale_f = nc.A(name, "scale_factor"); if(!a_fill) return Data(); fill = a_fill; if(a_offset_d) offset = a_offset_d; if(a_scale_d) scale = a_scale_d; if(a_offset_f) offset = a_offset_f; if(a_scale_f) scale = a_scale_f; } auto cn = GetCNames(nc); auto dn = GetDNames(nc); auto lons = nc.VR(cn.lonname); auto lats = nc.VR(cn.latname); if(!(lons && lats)) return Data(); auto lonb = lons(0); auto latb = lats(0); auto lone = lons(dn.nx - 1); auto late = lats(dn.ny - 1); auto lonstep = (lone - lonb) / (dn.nx - 1); auto latstep = (late - latb) / (dn.ny - 1); auto dom = DetGeoDomain(lonb, lone); real lon1 = ToGeoDomain(p->lonb, dom); real lon2 = ToGeoDomain(p->lone, dom); real lat1 = p->latb; real lat2 = p->late; // Special case when the longitude lies in a small sector between the end and the start if(lon1 < lonb) lon1 = lone; if(lon2 > lone) lon2 = lonb; auto yb = static_cast(Floor((lat1 - latb) / latstep)); auto ye = static_cast(Ceil((lat2 - latb) / latstep)); if(ye > dn.ny - 1) ye = dn.ny - 1; if(yb >= ye) return Data(); auto xb = static_cast(Floor((lon1 - lonb) / lonstep)); auto xe = static_cast(Ceil((lon2 - lonb) / lonstep)); if(xb == xe) return Data(); MString unit; { auto unitatt = nc.A(name, "units"); if(unitatt) unit = unitatt; } if(unit == "m s-1" || unit == "m/s") { unitmul = 100.0; unit = "cm/s"; } Data data((xb < xe) ? (xe - xb + 1) : (dn.nx + xe - xb + 1), ye - yb + 1, lons(xb), lats(yb), lonstep, latstep, std::move(unit)); if(xb < xe) { auto var = nc.V(name, {dn.lonname, xb, xe - xb + 1}, {dn.latname, yb, ye - yb + 1}); if(!var) return Data(); if(var.DimLen(0) != data.Nx() || var.DimLen(1) != data.Ny()) return Data(); for(size_t ix = 0; ix < var.DimLen(0); ix++) for(size_t iy = 0; iy < var.DimLen(1); iy++) { DataType v = var(ix, iy); data(ix, iy) = (v == fill) ? Data::Fillval() : ((v * scale + offset) * unitmul); } } else { auto var1 = nc.V(name, {dn.lonname, xb}, {dn.latname, yb, ye - yb + 1}); auto var2 = nc.V(name, {dn.lonname, 0, xe + 1}, {dn.latname, yb, ye - yb + 1}); if(!(var1 && var2)) return Data(); if((var1.DimLen(0) + var2.DimLen(0)) != data.Nx() || var1.DimLen(1) != data.Ny() || var2.DimLen(1) != data.Ny()) return Data(); for(size_t ix = 0; ix < var1.DimLen(0); ix++) for(size_t iy = 0; iy < var1.DimLen(1); iy++) { DataType v = var1(ix, iy); data(ix, iy) = (v == fill) ? Data::Fillval() : ((v * scale + offset) * unitmul); } for(size_t ix = 0; ix < var2.DimLen(0); ix++) for(size_t iy = 0; iy < var2.DimLen(1); iy++) { DataType v = var2(ix, iy); data(ix + var1.DimLen(0), iy) = (v == fill) ? Data::Fillval() : ((v * scale + offset) * unitmul); } } return data; }