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1 Commits

  1. 9
      CMakeLists.txt
  2. 44
      actions/actiongenintfile.h
  3. 130
      actions/actiongrad.cpp
  4. 133
      actions/actiongrad.h
  5. 210
      actions/actionint.h
  6. 10
      actions/actioninterpolate2d.cpp
  7. 181
      actions/actioninterpolate2d.h
  8. 22
      actions/actionmirror.h
  9. 85
      actions/actiontsc.h
  10. 118
      actions/actionuv.cpp
  11. 197
      actions/actionuv.h
  12. 195
      include/actiondep.h
  13. 18
      include/basedata.h
  14. 447
      include/cache.h
  15. 54
      include/copcat.h
  16. 36
      include/curlfuncs.h
  17. 51
      include/interpolation.h
  18. 11
      include/layereddata.h
  19. 207
      include/layereddataz.h
  20. 64
      include/mirrorfuncs.h
  21. 547
      include/ncfilew.h
  22. 207
      include/ncfuncs.h
  23. 87
      include/ncsimple.h
  24. 166
      include/nczarr.h
  25. 826
      include/nczarrcommon.h
  26. 206
      include/nczarrmulti.h
  27. 132
      include/simple2ddata.h
  28. 29
      include/traits.h
  29. 178
      include/zarr.h
  30. 2
      michlib
  31. 6
      sources/AVISO.h
  32. 26
      sources/AVISOLOCAL.cpp
  33. 4
      sources/AVISOLOCAL.h
  34. 9
      sources/BINFILE.h
  35. 222
      sources/COPERNICUS.cpp
  36. 21
      sources/COPERNICUS.h
  37. 86
      sources/GRIDVEL.cpp
  38. 50
      sources/GRIDVEL.h
  39. 6
      sources/HYCOM.h
  40. 7
      sources/MODISBINLOCAL.h
  41. 56
      sources/NEMO.h
  42. 6
      sources/NEMOBIO.h
  43. 129
      sources/TSCDATA.cpp
  44. 35
      sources/TSCDATA.h
  45. 526
      sources/VYLET.cpp
  46. 145
      sources/VYLET.h
  47. 13
      src/CMakeLists.txt
  48. 254
      src/cache.cpp
  49. 180
      src/copcat.cpp
  50. 41
      src/curlfuncs.cpp
  51. 102
      src/layereddata.cpp
  52. 295
      src/layereddataz.cpp
  53. 134
      src/mirrorfuncs.cpp
  54. 168
      src/ncfilew.cpp
  55. 129
      src/ncfuncs.cpp
  56. 231
      src/ncsimple.cpp
  57. 250
      src/zarr.cpp

9
CMakeLists.txt

@ -39,7 +39,7 @@ set(CMAKE_CXX_STANDARD_REQUIRED ON)
set(CMAKE_INTERPROCEDURAL_OPTIMIZATION ON)
include_directories(include sources sources-add GSW-C)
add_compile_options(-Wall -Wno-deprecated-declarations)
add_compile_options(-Wall)
# Dwarf-4 support check
include(CheckCXXCompilerFlag)
@ -54,13 +54,6 @@ if(COMPILER_SUPPORTS_ANALYZER AND STATIC_ANALYZER)
add_compile_options(-fanalyzer)
endif()
# Disable michlib warnings
add_compile_options(-Wno-deprecated-declarations)
CHECK_CXX_COMPILER_FLAG(-Wno-class-memaccess COMPILER_SUPPORTS_CLASSMEMACCESS)
if(COMPILER_SUPPORTS_CLASSMEMACCESS)
add_compile_options($<$<COMPILE_LANGUAGE:CXX>:-Wno-class-memaccess>)
endif()
add_library(teos STATIC GSW-C/gsw_oceanographic_toolbox.c GSW-C/gsw_saar.c)
set_target_properties(teos PROPERTIES LINKER_LANGUAGE C)

44
actions/actiongenintfile.h

@ -23,20 +23,6 @@ template<class D> MString ActionGenIntFile::DoAction(const CLArgs& args, D& ds)
if(!args.contains("out")) return "Output file name not specified";
VelSource mode = VelSource::AUTOSEL;
if(args.contains("geostrophic"))
{
auto modestr = args.at("geostrophic");
if(modestr == "" || modestr == "ssh")
mode = VelSource::GEOSTROPHICSSH;
else if(modestr == "surf" || modestr == "surface")
mode = VelSource::GEOSTROPHIC;
else if(modestr == "nongeo")
mode = VelSource::STANDART;
else
return "Parameter \"geostrophic\" have incorrect value " + modestr;
}
auto [tindexes, err] = GetTIndexes(ds, args, pars);
if(err.Exist()) return err;
if(tindexes.size() < 10) return "Too few time moments";
@ -70,7 +56,7 @@ template<class D> MString ActionGenIntFile::DoAction(const CLArgs& args, D& ds)
for(size_t it = 0; it < tindexes.size(); it++)
{
auto data = ReadUV(ds, p, tindexes[it], mode);
auto data = ReadUV(ds, p, tindexes[it]);
if(!data) return "Can't read data";
if(it == 0)
{
@ -81,32 +67,9 @@ template<class D> MString ActionGenIntFile::DoAction(const CLArgs& args, D& ds)
fw.SetParameter("dx", data.XStep() * 60.0);
fw.SetParameter("dy", data.YStep() * 60.0);
fw.SetParameter("nt", tindexes.size());
fw.SetParameter("dt", (ds.Time(tindexes[1]) - ds.Time(tindexes[0])).D());
fw.SetParameter("dt", (ds.Time(tindexes[1]) - ds.Time(tindexes[0])) / 86400.0);
fw.SetParameter("FillValue", data.Fillval());
fw.UsePrefix("Info");
switch(mode)
{
case(VelSource::AUTOSEL):
{
fw.SetParameter("Mode", "autoselect between standart and geostrophic");
break;
}
case(VelSource::STANDART):
{
fw.SetParameter("Mode", "standart");
break;
}
case(VelSource::GEOSTROPHIC):
{
fw.SetParameter("Mode", "geostrophic");
break;
}
case(VelSource::GEOSTROPHICSSH):
{
fw.SetParameter("Mode", "geostrophic from ssh");
break;
}
}
fw.SetParameter("lonb", lonb);
fw.SetParameter("latb", latb);
fw.SetParameter("lone", lone);
@ -126,9 +89,8 @@ template<class D> MString ActionGenIntFile::DoAction(const CLArgs& args, D& ds)
fw.SetParameter("dotxdotylonlat2v", "(1.852/0.864)*%doty");
fw.SetParameter("BeginDate", ds.Time(tindexes.front()).ToTString());
fw.SetParameter("EndDate", ds.Time(tindexes.back()).ToTString());
fw.SetParameter("Timestep", (ds.Time(tindexes[1]) - ds.Time(tindexes[0])).Seconds());
fw.SetParameter("Timestep", ds.Time(tindexes[1]) - ds.Time(tindexes[0]));
fw.SetParameter("DataID", michlib::UniqueId());
fw.SetParameter("Creation command", args.at("_cmdline"));
}
for(size_t ilat = 0; ilat < data.Ny(); ilat++)

130
actions/actiongrad.cpp

@ -1,130 +0,0 @@
#define MICHLIB_NOSOURCE
#include "actiongrad.h"
MString GradMethods::NCFileW::Create(const MString& name, const MString& history, const std::vector<MString>& vnames, const std::vector<MString>& lnames,
const std::vector<GradMethods::DataType>& lons, const std::vector<GradMethods::DataType>& lats, int compress)
{
const float node_offset = 0.0;
auto nx = lons.size();
auto ny = lats.size();
const auto fill = static_cast<GradMethods::DataType>(std::numeric_limits<GradMethods::Matrix::MDataType>::max());
// Creating
Open(name);
if(!*this) return "Can't create netcdf file " + name + ": " + ErrMessage();
AddAtt("history", history);
AddAtt("node_offset", node_offset);
AddDim("longitude", nx);
AddDim("latitude", ny);
AddVar("longitude", NC_FLOAT, "longitude");
AddVar("latitude", NC_FLOAT, "latitude");
SetComp("longitude", compress);
SetComp("latitude", compress);
AddAtt("longitude", "standard_name", "longitude");
AddAtt("longitude", "long_name", "Longitude");
AddAtt("latitude", "standard_name", "latitude");
AddAtt("latitude", "long_name", "Latitude");
// Variables
for(size_t i = 0; i < vnames.size(); i++)
{
AddVar(vnames[i], NC_FLOAT, "latitude", "longitude");
SetComp(vnames[i], compress);
if(lnames[i].Exist()) AddAtt(vnames[i], "long_name", lnames[i]);
AddAtt(vnames[i], "_FillValue", fill);
}
// End definitions
EndDef();
// Writing lon, lat
WriteVar("longitude", lons.data());
WriteVar("latitude", lats.data());
if(!*this) return "Can't set grid in the netcdf file " + name + ": " + ErrMessage();
return "";
}
MString GradMethods::NCFileW::WriteVariable(const MString& name, const GradMethods::Matrix& data)
{
WriteVar(name, data.Data().data());
if(!*this) return "Can't write variable " + name + ": " + ErrMessage();
return "";
}
GradMethods::Matrix::Matrix(const std::vector<GradMethods::DataType>& in, size_t nx_, size_t ny_, struct GradMethods::MinMax minmax): nx(nx_), ny(ny_), data(nx_ * ny_)
{
if(minmax.automin || minmax.automax)
{
DataType min = in[0];
DataType max = in[0];
for(size_t i = 1; i < in.size(); i++)
if(in[i] != minmax.fill)
{
min = std::min(min, in[i]);
max = std::max(max, in[i]);
}
if(minmax.automin) minmax.min = min;
if(minmax.automax) minmax.max = max;
}
if(minmax.log)
{
minmax.min = michlib_internal::RealType<sizeof(DataType)>::Log(minmax.min);
minmax.max = michlib_internal::RealType<sizeof(DataType)>::Log(minmax.max);
}
DataType a = (std::numeric_limits<MDataType>::max() - 1) / (minmax.max - minmax.min);
for(size_t i = 1; i < in.size(); i++)
{
DataType v = minmax.log ? michlib_internal::RealType<sizeof(DataType)>::Log(in[i]) : in[i];
if(in[i] == minmax.fill)
data[i] = std::numeric_limits<MDataType>::max();
else if(v <= minmax.min)
data[i] = 0;
else if(v >= minmax.max)
data[i] = std::numeric_limits<MDataType>::max() - 1;
else
data[i] = static_cast<MDataType>(michlib_internal::RealType<sizeof(DataType)>::Round(a * (v - minmax.min)));
}
}
void GradMethods::Matrix::Grad()
{
std::vector<MDataType> out(data.size());
const auto bad = std::numeric_limits<MDataType>::max();
for(size_t iy = 0; iy < ny; iy++)
for(size_t ix = 0; ix < nx; ix++)
{
if(iy < 1 || ix < 1 || iy > ny - 2 || ix > nx - 2)
out[iy * nx + ix] = bad;
else if(V(ix - 1, iy - 1) == bad || V(ix, iy - 1) == bad || V(ix + 1, iy - 1) == bad || V(ix - 1, iy) == bad || V(ix, iy) == bad || V(ix + 1, iy) == bad ||
V(ix - 1, iy + 1) == bad || V(ix, iy + 1) == bad || V(ix + 1, iy + 1) == bad)
out[iy * nx + ix] = bad;
else
{
using IT = michlib::int4;
// Possible but unlikely overflow
const IT m1 = -1;
const IT m2 = -2;
const IT p1 = 1;
const IT p2 = 2;
IT gx = m1 * V(ix - 1, iy + 1) + p1 * V(ix + 1, iy + 1) + m2 * V(ix - 1, iy) + p2 * V(ix + 1, iy) + m1 * V(ix - 1, iy - 1) + p1 * V(ix + 1, iy - 1);
IT gy = m1 * V(ix - 1, iy - 1) + p1 * V(ix - 1, iy + 1) + m2 * V(ix, iy - 1) + p2 * V(ix, iy + 1) + m1 * V(ix + 1, iy - 1) + p1 * V(ix + 1, iy + 1);
auto sq = static_cast<IT>(michlib::Round(michlib::Hypot(gx, gy)));
if(sq >= bad) sq = bad - 1;
out[iy * nx + ix] = static_cast<MDataType>(sq);
}
}
data = std::move(out);
}

133
actions/actiongrad.h

@ -1,133 +0,0 @@
#pragma once
#include "actiondep.h"
#include "ncfilew.h"
#include "ncfuncs.h"
class GradMethods
{
public:
using DataType = float;
static DataType ToNum(const MString& str) { return michlib_internal::RealType<sizeof(DataType)>::String2Real(str.Buf()); }
struct MinMax
{
bool automin, automax, log;
DataType min, max;
DataType fill;
};
class Matrix;
class NCFileW;
};
class GradMethods::Matrix
{
public:
using MDataType = michlib::uint2;
private:
size_t nx, ny;
std::vector<MDataType> data;
public:
Matrix(const std::vector<DataType>& in, size_t nx_, size_t ny_, struct MinMax minmax);
void Grad();
auto Nx() const { return nx; }
auto Ny() const { return ny; }
const auto& V(size_t ix, size_t iy) const { return data[iy * nx + ix]; }
auto& V(size_t ix, size_t iy) { return data[iy * nx + ix]; }
const auto& Data() const { return data; }
};
class GradMethods::NCFileW: public NCFileWBase
{
public:
MString Create(const MString& name, const MString& history, const std::vector<MString>& vnames, const std::vector<MString>& lnames, const std::vector<GradMethods::DataType>& lons,
const std::vector<GradMethods::DataType>& lats, int compress);
MString WriteVariable(const MString& name, const GradMethods::Matrix& data);
};
template<class T>
concept GradSupported = requires(T t, const MString& vname) {
{
t.ReadVar(vname)
} -> std::same_as<std::vector<GradMethods::DataType>>;
};
ADD_ACTION(GRAD, grad, GradSupported<Source>, GradMethods);
template<class D> MString ActionGRAD::DoAction(const CLArgs& args, D& ds)
{
auto resop = ds.Open(args);
if(resop.Exist()) return "Can't open source: " + resop;
MString name = args.contains("out") ? args.at("out") : "out.nc";
MString min = args.contains("min") ? args.at("min") : "auto";
MString max = args.contains("max") ? args.at("max") : "auto";
int compress = args.contains("compress") ? args.at("compress").ToInt() : 3;
std::vector<Matrix> data;
std::vector<MString> lnames;
// Read data
for(size_t i = 0; i < ds.NVar(); i++)
{
const MString& name = ds.VarNames()[i];
const MString& lname = ds.LongNames()[i];
bool hmin = args.contains(name + "_min");
bool hmax = args.contains(name + "_max");
struct MinMax minmax;
minmax.log = args.contains(name + "_log");
if(hmin)
{
MString vmin = args.at(name + "_min");
minmax.automin = (vmin == "auto");
minmax.min = ToNum(vmin);
}
else
{
minmax.automin = (min == "auto");
minmax.min = ToNum(min);
}
if(hmax)
{
MString vmax = args.at(name + "_max");
minmax.automax = (vmax == "auto");
minmax.max = ToNum(vmax);
}
else
{
minmax.automax = (max == "auto");
minmax.max = ToNum(max);
}
minmax.fill = ds.FillVal(name);
data.emplace_back(ds.ReadVar(name), ds.Nx(), ds.Ny(), minmax);
lnames.emplace_back(lname + ", gradient");
}
NCFileW fw;
fw.Create(name, (ds.History().Exist() ? (ds.History() + "; ") : "") + args.at("_cmdline"), ds.VarNames(), lnames, ds.ReadLons(), ds.ReadLats(), compress);
for(size_t i = 0; i < ds.NVar(); i++)
{
const MString& name = ds.VarNames()[i];
data[i].Grad();
fw.WriteVariable(name, data[i]);
}
return "";
};

210
actions/actionint.h

@ -1,210 +0,0 @@
#pragma once
#include "BFileR.h"
#include "BFileW.h"
#include "actiondep.h"
#include "interpolation.h"
#include "ncfilew.h"
#include "ncfuncs.h"
#include <memory>
template<class T>
concept ReadIsInterpolable = requires {
{
std::declval<ReadType<T>>().GridPos(0.0, 0.0)
} -> std::convertible_to<struct GridPoint>;
};
ADD_ACTION(INT, int, (ReadPSupported<Source> || ReadSupported<Source>)&&ReadIsInterpolable<Source>);
template<class D> MString ActionINT::DoAction(const CLArgs& args, D& ds)
{
struct TPoint
{
struct Point2D p;
MDateTime t;
real lon0, lat0, dtime;
};
MDateTime refdate("1980-01-01");
if(!args.contains("input")) return "No input file given";
michlib::BFileR in;
if(in.Open(args.at("input")) != ERR_NOERR) return "Can't open input file " + args.at("input");
std::vector<TPoint> points;
struct Region reg;
{
michlib::uint loncol = in.Columns(), latcol = in.Columns(), timecol = in.Columns();
michlib::uint lon0col = in.Columns(), lat0col = in.Columns(), dtimecol = in.Columns();
for(uint i = 0; i < in.Columns(); i++)
{
if(in.ColumnName(i + 1) == "lon") loncol = i;
if(in.ColumnName(i + 1) == "lat") latcol = i;
if(in.ColumnName(i + 1) == "rtime") timecol = i;
if(in.ColumnName(i + 1) == "lon0") lon0col = i;
if(in.ColumnName(i + 1) == "lat0") lat0col = i;
if(in.ColumnName(i + 1) == "time") dtimecol = i;
}
if(loncol >= in.Columns()) return "Lon column not found in input file " + args.at("input");
if(latcol >= in.Columns()) return "Lat column not found in input file " + args.at("input");
if(timecol >= in.Columns()) return "Time column not found in input file " + args.at("input");
if(lon0col >= in.Columns()) return "Lon0 column not found in input file " + args.at("input");
if(lat0col >= in.Columns()) return "Lat0 column not found in input file " + args.at("input");
if(dtimecol >= in.Columns()) return "Age column not found in input file " + args.at("input");
points.resize(in.Rows());
reg.lonb = reg.lone = in[loncol][0];
reg.latb = reg.late = in[latcol][0];
for(uint i = 0; i < in.Rows(); i++)
{
points[i].p.x = in[loncol][i];
points[i].p.y = in[latcol][i];
points[i].t = refdate + static_cast<time_t>(michlib::Round(in[timecol][i] * 86400));
points[i].lon0 = in[lon0col][i];
points[i].lat0 = in[lat0col][i];
points[i].dtime = in[dtimecol][i];
reg.lonb = std::min(reg.lonb, points[i].p.x);
reg.lone = std::max(reg.lone, points[i].p.x);
reg.latb = std::min(reg.latb, points[i].p.y);
reg.late = std::max(reg.late, points[i].p.y);
}
std::ranges::sort(points, {}, &TPoint::t);
}
in.Close();
auto resop = ds.Open(args);
if(resop.Exist()) return "Can't open source: " + resop;
michlib_internal::ParameterListEx pars;
pars.UsePrefix("");
pars.SetParameter("source", args.at("source"));
pars.SetParameter("history", args.at("_cmdline"));
MString varstring;
if(args.contains("var"))
varstring = args.at("var");
else
{
if(args.contains("vars"))
varstring = args.at("vars");
else
{
if constexpr(HasDefVars<D>)
varstring = ds.DefaultVars();
else
return "Variables not specified";
}
}
auto vlist = michlib::Split_on_words(varstring, " ,", false);
std::vector<MString> vnames{std::make_move_iterator(std::begin(vlist)), std::make_move_iterator(std::end(vlist))};
{
std::set<MString> used;
for(const auto& vname: vnames)
{
if(used.contains(vname)) return "Duplicate variable " + vname + " in list " + varstring;
if(ds.CheckVar(vname) == VarPresence::NONE) return "Variable " + vname + " not exists in this dataset";
used.insert(vname);
}
}
pars.SetParameter("variables", varstring);
//int compress = 3;
//if(args.contains("compress")) compress = args.at("compress").ToInt();
std::unique_ptr<const BaseParameters> sourcepars;
if constexpr(ParametersSupported<D>)
{
if constexpr(ParametersRequiredRegion<D>)
{
auto [p, err] = ds.Parameters(pars, args, reg);
if(err.Exist()) return err;
sourcepars.reset(p);
}
else
{
auto [p, err] = ds.Parameters(pars, args);
if(err.Exist()) return err;
sourcepars.reset(p);
}
}
auto p = sourcepars.get();
MString name = args.contains("out") ? args.at("out") : "out.bin";
//MString outfmt = args.contains("format") ? args.at("format") : (GetExt(name) == "nc" ? "nc" : "bin");
size_t loind = ds.NTimes(), hiind = ds.NTimes(), curind = 0;
michlib::BFileW fw;
const MDateTime first = ds.Time(0), last = ds.Time(ds.NTimes() - 1);
std::vector<LinearInterpolator<ReadType<D>>> lo, hi;
{
size_t ic = 0;
fw.Create(name, 6 + vnames.size());
fw.SetColumnName(++ic, "lon0");
fw.SetColumnName(++ic, "lat0");
fw.SetColumnName(++ic, "lon");
fw.SetColumnName(++ic, "lat");
fw.SetColumnName(++ic, "time");
fw.SetColumnName(++ic, "rtime");
for(size_t i = 0; i < vnames.size(); i++) fw.SetColumnName(++ic, vnames[i]);
fw.SetParameters(pars);
}
for(size_t i = 0; i < points.size(); i++)
{
if(points[i].t < first || points[i].t > last) continue;
while(!(points[i].t >= ds.Time(curind) && points[i].t <= ds.Time(curind + 1))) curind++;
if(curind != loind && curind != hiind)
{
loind = curind;
hiind = curind + 1;
{
auto temp = Read(ds, vnames, p, loind);
if(temp.size() != vnames.size()) return "Can't read data";
//lo.resize(temp.size());
for(size_t j = 0; j < temp.size(); j++) lo.emplace_back(std::move(temp[j]));
}
{
auto temp = Read(ds, vnames, p, hiind);
if(temp.size() != vnames.size()) return "Can't read data";
//hi.resize(temp.size());
for(size_t j = 0; j < temp.size(); j++) hi.emplace_back(std::move(temp[j]));
}
}
else if(curind == hiind)
{
loind = curind;
hiind = curind + 1;
lo = std::move(hi);
{
auto temp = Read(ds, vnames, p, hiind);
if(temp.size() != vnames.size()) return "Can't read data";
//hi.resize(temp.size());
for(size_t j = 0; j < temp.size(); j++) hi.emplace_back(std::move(temp[j]));
}
}
auto step = (ds.Time(hiind) - ds.Time(loind)).S();
auto delta = (points[i].t - ds.Time(loind)).S();
real trel = delta / step;
fw.Write(points[i].lon0);
fw.Write(points[i].lat0);
fw.Write(points[i].p.x);
fw.Write(points[i].p.y);
fw.Write(points[i].dtime);
fw.Write(DeltaDates(refdate, points[i].t));
for(size_t iv = 0; iv < lo.size(); iv++)
{
real vlo = lo[iv](points[i].p);
real vhi = hi[iv](points[i].p);
fw.Write(vlo + (vhi - vlo) * trel);
}
}
fw.Finalize();
fw.Close();
return "";
};

10
actions/actioninterpolate2d.cpp

@ -0,0 +1,10 @@
#define MICHLIB_NOSOURCE
#include "actioninterpolate2d.h"
InterpolateMethods::Mode InterpolateMethods::GetMode(const CLArgs& args)
{
MString mode = args.contains("mode") ? args.at("mode") : "vylet_start";
if(mode == "vylet_start") return Mode::VYLETSTART;
if(mode == "vylet_end") return Mode::VYLETEND;
return Mode::INVALID;
}

181
actions/actioninterpolate2d.h

@ -0,0 +1,181 @@
#pragma once
#include "BFileR.h"
#include "actiondep.h"
//using michlib::message;
class InterpolateMethods
{
protected:
enum class Mode
{
INVALID,
VYLETSTART,
VYLETEND
};
struct DataPoint
{
real lon, lat;
MDateTime t;
};
class VyletFile
{
michlib::BFileR fr;
bool invtime;
bool usestart;
MDateTime beg, end, t0;
michlib::CompiledParser xy2lon, xy2lat;
real x, y;
public:
MString Open(const MString& name, Mode mode);
};
static Mode GetMode(const CLArgs& args);
};
ADD_ACTION(Interpolate, interpolate, CanInterpolate2D<Source>, InterpolateMethods);
template<class D> MString ActionInterpolate::DoAction(const CLArgs& args, D& ds)
{
Mode mode = GetMode(args);
if(mode == Mode::INVALID) return "Unknown mode";
if(!args.contains("in")) return "No vylet data file specified";
MString in = args.at("in");
if(!args.contains("out")) return "No output file specified";
MString out = args.at("out");
michlib::BFileR fr;
if(fr.Open(in) != ERR_NOERR) return "Can't open file " + in;
std::vector<struct DataPoint> datapoints;
{
bool invtime;
{
fr.UsePrefix("");
MString method = fr.ParameterSValue("Method", "");
if(method == "Bicubic" || method == "BicubicL")
invtime = false;
else if(method == "BicubicI" || method == "BicubicIL")
invtime = true;
else
return "Unknown method in the file " + in;
}
MDateTime beg, end;
{
fr.UsePrefix("Datafile_Info");
MString s;
s = fr.ParameterSValue("BeginDate", "");
beg.FromString(s);
s = fr.ParameterSValue("EndDate", "");
end.FromString(s);
}
MDateTime t0;
{
fr.UsePrefix("");
auto tbeg = static_cast<time_t>(fr.ParameterRValue("tbeg", 0.0) * 86400);
if(invtime)
{
t0 = end;
t0.AddSeconds(-tbeg);
}
else
{
t0 = beg;
t0.AddSeconds(tbeg);
}
}
michlib::CompiledParser xy2lon, xy2lat;
real x, y;
michlib::ParserVars pv;
pv["x"] = &x;
pv["y"] = &y;
fr.UsePrefix("Datafile_Info");
if(!ArifmeticCompiler(fr.ParameterSValue("xy2lon", ""), xy2lon, &pv)) return "Can't find xy2lon in the file " + in;
if(!ArifmeticCompiler(fr.ParameterSValue("xy2lat", ""), xy2lat, &pv)) return "Can't find xy2lat in the file " + in;
auto resop = ds.Open(args);
if(resop.Exist()) return "Can't open source: " + resop;
for(size_t i = 0; i < fr.Rows(); i++)
{
if(mode == Mode::VYLETSTART)
{
x = fr[0][i];
y = fr[1][i];
real lon, lat;
xy2lon.Run(lon);
xy2lat.Run(lat);
datapoints.emplace_back(lon, lat, t0);
}
if(mode == Mode::VYLETEND)
{
x = fr[2][i];
y = fr[3][i];
real lon, lat;
xy2lon.Run(lon);
xy2lat.Run(lat);
time_t t = static_cast<time_t>(fr[4][i] * 86400);
MDateTime time = invtime ? end : beg;
time.AddSeconds((invtime ? -1 : 1) * t);
datapoints.emplace_back(lon, lat, time);
}
}
}
if(datapoints.size() == 0) return "No data readed from file " + in;
struct Region reg;
reg.lonb = datapoints[0].lon;
reg.lone = datapoints[0].lon;
reg.latb = datapoints[0].lat;
reg.late = datapoints[0].lat;
for(const auto& p: datapoints)
{
if(p.lon < reg.lonb) reg.lonb = p.lon;
if(p.lat < reg.latb) reg.latb = p.lat;
if(p.lon > reg.lone) reg.lone = p.lon;
if(p.lat > reg.late) reg.late = p.lat;
}
return "";
/*
if(!args.contains("var")) return "Variable not specified";
MString vname = args.at("var");
if(!ds.CheckVar(vname)) return "Variable " + vname + " not exists in this dataset";
pars.SetParameter("variable", vname);
std::unique_ptr<const BaseParameters> sourcepars;
if constexpr(ParametersSupported<D>)
{
if constexpr(ParametersRequiredRegion<D>)
{
auto [p, err] = ds.Parameters(pars, args, reg);
if(err.Exist()) return err;
sourcepars.reset(p);
}
else
{
auto [p, err] = ds.Parameters(pars, args);
if(err.Exist()) return err;
sourcepars.reset(p);
}
}
auto p = sourcepars.get();
auto data = Read(ds, vname, p, tindexes);
if(!data) return "Can't read data";
return "";
*/
};

22
actions/actionmirror.h

@ -1,22 +0,0 @@
#pragma once
#include "actiondep.h"
#include "merrors.h"
using michlib::message;
using michlib::Error;
template<class T>
concept MirrorSupported = requires(T t, const CLArgs& args) {
{
t.Mirror(args)
} -> std::convertible_to<Error>;
};
ADD_ACTION(Mirror, mirror, MirrorSupported<Source>);
template<class D> MString ActionMirror::DoAction(const CLArgs& args, D& data)
{
auto res = data.Mirror(args);
if(!res) return "Mirroring failed";
return "";
};

85
actions/actiontsc.h

@ -20,7 +20,6 @@ template<class D> MString ActionTSC::DoAction(const CLArgs& args, D& ds)
michlib_internal::ParameterListEx pars;
pars.UsePrefix("");
pars.SetParameter("source", args.at("source"));
pars.SetParameter("history", args.at("_cmdline"));
auto [tindexes, err] = GetTIndexes(ds, args, pars);
if(err.Exist()) return err;
@ -41,15 +40,6 @@ template<class D> MString ActionTSC::DoAction(const CLArgs& args, D& ds)
}
}
bool average = args.contains("average");
bool gradient = args.contains("gradient");
if(gradient)
if constexpr(!ReadIs2DGeoArray<D>) return "Gradient calculation not supported for this source";
int compress = 3;
if(args.contains("compress")) compress = args.at("compress").ToInt();
auto vlist = michlib::Split_on_words(varstring, " ,", false);
std::vector<MString> vnames{std::make_move_iterator(std::begin(vlist)), std::make_move_iterator(std::end(vlist))};
{
@ -57,7 +47,7 @@ template<class D> MString ActionTSC::DoAction(const CLArgs& args, D& ds)
for(const auto& vname: vnames)
{
if(used.contains(vname)) return "Duplicate variable " + vname + " in list " + varstring;
if(ds.CheckVar(vname) == VarPresence::NONE) return "Variable " + vname + " not exists in this dataset";
if(!ds.CheckVar(vname)) return "Variable " + vname + " not exists in this dataset";
used.insert(vname);
}
}
@ -82,28 +72,19 @@ template<class D> MString ActionTSC::DoAction(const CLArgs& args, D& ds)
}
auto p = sourcepars.get();
TimeData tdata(ds, tindexes);
MString name = args.contains("out") ? args.at("out") : "out.bin";
MString outfmt = args.contains("format") ? args.at("format") : (GetExt(name) == "nc" ? "nc" : "bin");
if(outfmt == "bin" && !average && tindexes.size() > 1) return "Multiple time moments does'nt supported by the bin format";
bool headwrited = false;
NCFileW ncfw;
for(size_t it = 0; it < tindexes.size(); it++)
{
auto data = average ? Read(ds, vnames, p, tindexes) : Read(ds, vnames, p, tindexes[it]);
auto data = Read(ds, vnames, p, tindexes);
if(data.size() != vnames.size()) return "Can't read data";
if(!headwrited)
for(size_t i = 0; i < vnames.size(); i++)
{
if(!data[i].Unit().Exist()) michlib::errmessage("Unknown measurement unit for variable " + vnames[i] + "!");
if(!data[i].StandartName().Exist()) data[i].SetStandartName(NCFuncs::Name2StName(vnames[i]));
if(!data[i].LongName().Exist()) data[i].SetLongName(NCFuncs::Name2LongName(vnames[i]));
if(!data[i].LongName().Exist()) data[i].SetStandartName(NCFuncs::Name2LongName(vnames[i]));
}
MString name = args.contains("out") ? args.at("out") : "out.bin";
MString outfmt = args.contains("format") ? args.at("format") : (GetExt(name) == "nc" ? "nc" : "bin");
if(outfmt == "bin")
{
BFileW fw;
@ -112,60 +93,38 @@ template<class D> MString ActionTSC::DoAction(const CLArgs& args, D& ds)
fw.Create(name, 2 + data.size());
fw.SetColumnName(++ic, "Longitude");
fw.SetColumnName(++ic, "Latitude");
for(size_t i = 0; i < data.size(); i++)
fw.SetColumnName(++ic, (gradient ? "gradient of " : "") + vnames[i] + ", " + (data[i].Unit().Exist() ? data[i].Unit() : "unknown") + (gradient ? "/km" : ""));
for(size_t i = 0; i < data.size(); i++) fw.SetColumnName(++ic, vnames[i] + ", " + (data[i].Unit().Exist() ? data[i].Unit() : "unknown"));
fw.SetParameters(pars);
for(size_t r = 0; r < data[0].N(); r++)
{
fw.Write(data[0].Lon(r));
fw.Write(data[0].Lat(r));
if(gradient)
{
if constexpr(ReadIs2DGeoArray<D>)
for(size_t i = 0; i < data.size(); i++)
{
auto val = data[i].Grad(r);
fw.Write(val == data[i].Fillval() ? NAN : val);
}
}
else
for(size_t i = 0; i < data.size(); i++) fw.Write(data[i].IsFill(r) ? NAN : data[i](r));
}
fw.Finalize();
fw.Close();
return "";
}
else if(outfmt == "nc" || outfmt == "netcdf")
if(outfmt == "nc" || outfmt == "netcdf")
{
int compress = 3;
NCFileW fw;
MString err;
if(!err.Exist() && !headwrited) err = ncfw.Create(data[0], name, compress);
if(!err.Exist() && !headwrited) err = ncfw.AddTimeData(tdata, !average);
if(!err.Exist() && !headwrited) err = ncfw.AddAtts(pars);
if(args.contains("compress")) compress = args.at("compress").ToInt();
if(!err.Exist()) err = fw.Create(data[0], name, args.at("_cmdline"), compress);
for(size_t i = 0; i < data.size(); i++)
if(!err.Exist() && !headwrited)
err = ncfw.AddVariable((gradient ? "G" : "") + vnames[i], data[i].StandartName(), data[i].LongName(), data[i].Unit() + (gradient ? "/km" : ""), data[i].Comment());
if(!err.Exist() && !headwrited) err = ncfw.WriteGrid(data[0]);
if(!err.Exist()) err = fw.AddVariable(vnames[i], data[i].StandartName(), data[i].LongName(), data[i].Unit(), data[i].Comment());
if(!err.Exist()) err = fw.WriteGrid(data[0]);
for(size_t i = 0; i < data.size(); i++)
if(!err.Exist())
{
if(gradient)
{
if constexpr(ReadIs2DGeoArray<D>)
err = average ? ncfw.WriteVariable(data[i], "G" + vnames[i], [&data = std::as_const(data[i])](size_t i, size_t j) { return data.Grad(i, j); })
: ncfw.WriteVariable(data[i], "G" + vnames[i], [&data = std::as_const(data[i])](size_t i, size_t j) { return data.Grad(i, j); }, it);
}
else
err = average ? ncfw.WriteVariable(data[i], vnames[i]) : ncfw.WriteVariable(data[i], vnames[i], it);
}
if(!err.Exist()) err = fw.WriteVariable(data[i], vnames[i]);
if(err.Exist()) return err;
}
else
return "Unknown format: " + outfmt;
fw.Close();
if(average) break;
headwrited = true;
return "";
}
ncfw.Close();
return "";
return "Unknown format: " + outfmt;
};

118
actions/actionuv.cpp

@ -1,14 +1,13 @@
#define MICHLIB_NOSOURCE
#include "actionuv.h"
void UVMethods::StPoints::WriteBinBile(const MString& name, const michlib_internal::ParameterListEx& pars) const
void UVMethods::StPoints::WriteBinBile(const MString& name) const
{
BFileW stp;
stp.Create(name, 3);
stp.SetColumnName(1, lonlat ? "Longitude" : "x");
stp.SetColumnName(2, lonlat ? "Latitude" : "x");
stp.SetColumnName(3, "Stability (0 - saddle, 1 - st. anticicl. focus, 2 - st. knot, 3 - unst. anticicl. focus, 4 - unst. knot, 5 - st. cicl. focus, 6 - unst. cicl. focus)");
stp.SetParameters(pars);
for(size_t i = 0; i < N(); i++)
{
@ -20,85 +19,70 @@ void UVMethods::StPoints::WriteBinBile(const MString& name, const michlib_intern
stp.Close();
}
MString UVMethods::StPoints::CreateNcFile(const MString& name, const michlib_internal::ParameterListEx& pars, const MString& history, int comp, const TimeData& tdata, bool timedep)
MString UVMethods::StPoints::WriteNcFile(const MString& name, const MString& history, int comp) const
{
tdep = timedep;
int ret;
int ncid;
int dimid;
int xid, yid, tid;
MString text;
const MString xname = lonlat ? "longitude" : "x";
const MString yname = lonlat ? "latitude" : "y";
ret = nc_create(name.Buf(), NC_CLOBBER | NC_NETCDF4, &ncid);
if(ret != NC_NOERR) return "Can't create netcdf file: " + name;
nc.Open(name);
if(!nc) return "Can't create netcdf file " + name + ": " + nc.ErrMessage();
ret = nc_put_att_text(ncid, NC_GLOBAL, "history", history.Len() + 1, history.Buf());
if(ret != NC_NOERR) return "Can't write history attribute in the netcdf file";
nc.AddAtt("history", history);
nc.AddAtts(pars);
nc.AddDim("i", N());
nc.AddDim("time", tdata.steps.size());
ret = nc_def_dim(ncid, "i", N(), &dimid);
if(ret != NC_NOERR) return "Can't create dimension in the netcdf file";
nc.AddVar("time", decltype(nc)::Type2NCType<decltype(tdata.steps)::value_type>, "time");
nc.SetComp("time", comp);
nc.AddAtt("time", "standard_name", "time");
nc.AddAtt("time", "long_name", "time");
nc.AddAtt("time", "units", tdata.UnitName());
if(tdep)
{
nc.AddVar(xname, NC_FLOAT, "time", "i");
nc.AddVar(yname, NC_FLOAT, "time", "i");
}
else
{
nc.AddVar(xname, NC_FLOAT, "i");
nc.AddVar(yname, NC_FLOAT, "i");
}
nc.SetComp(xname, comp);
nc.SetComp(yname, comp);
ret = nc_def_var(ncid, lonlat ? "longitude" : "x", NC_FLOAT, 1, &dimid, &xid);
if(ret != NC_NOERR) return "Can't create x variable in the netcdf file";
ret = nc_def_var(ncid, lonlat ? "latitude" : "y", NC_FLOAT, 1, &dimid, &yid);
if(ret != NC_NOERR) return "Can't create y variable in the netcdf file";
if(lonlat)
{
nc.AddAtt(xname, "standard_name", "longitude");
nc.AddAtt(xname, "long_name", "Longitude");
nc.AddAtt(yname, "standard_name", "latitude");
nc.AddAtt(yname, "long_name", "Latitude");
}
else
{
nc.AddAtt(xname, "long_name", "x-coordinate");
nc.AddAtt(yname, "long_name", "y-coordinate");
text = "longitude";
ret = nc_put_att_text(ncid, xid, "standard_name", text.Len() + 1, text.Buf());
if(ret != NC_NOERR) return "Can't write standard_name attribute of longitude variable in the netcdf file";
text = "latitude";
ret = nc_put_att_text(ncid, yid, "standard_name", text.Len() + 1, text.Buf());
if(ret != NC_NOERR) return "Can't write standard_name attribute of latitude variable in the netcdf file";
}
if(tdep)
nc.AddVar("type", NC_UBYTE, "time", "i");
else
nc.AddVar("type", NC_UBYTE, "i");
nc.SetComp("type", comp);
nc.AddAtt("type", "long_name",
"Stationary point type, 0 - saddle, 1 - st. anticicl. focus, 2 - st. knot, 3 - unst. anticicl. focus, 4 - unst. knot, 5 - st. cicl. focus, 6 - unst. cicl. focus");
ret = nc_def_var_deflate(ncid, xid, 1, 1, comp);
if(ret != NC_NOERR) return "Can't set deflate parameters for x variable in the netcdf file";
ret = nc_def_var_deflate(ncid, yid, 1, 1, comp);
if(ret != NC_NOERR) return "Can't set deflate parameters for y variable in the netcdf file";
nc.WriteVar("time", tdata.steps.data());
ret = nc_def_var(ncid, "type", NC_UBYTE, 1, &dimid, &tid);
if(ret != NC_NOERR) return "Can't create type variable in the netcdf file";
ret = nc_def_var_deflate(ncid, tid, 1, 1, comp);
if(ret != NC_NOERR) return "Can't set deflate parameters for type variable in the netcdf file";
text = "Stationary point type, 0 - saddle, 1 - st. anticicl. focus, 2 - st. knot, 3 - unst. anticicl. focus, 4 - unst. knot, 5 - st. cicl. focus, 6 - unst. cicl. focus";
ret = nc_put_att_text(ncid, tid, "long_name", text.Len() + 1, text.Buf());
if(ret != NC_NOERR) return "Can't write long_name attribute of type variable in the netcdf file";
if(!nc) return "Can't set grid in the netcdf file " + name + ": " + nc.ErrMessage();
return "";
}
ret = nc_enddef(ncid);
if(ret != NC_NOERR) return "Can't finish definition of the netcdf file";
MString UVMethods::StPoints::WriteNcFile(size_t it)
{
const MString xname = lonlat ? "longitude" : "x";
const MString yname = lonlat ? "latitude" : "y";
const size_t i = 0, c = N();
float buf[c];
if(tdep)
{
nc.WriteVar(xname, it, x.data());
nc.WriteVar(yname, it, y.data());
nc.WriteVar("type", it, t.data());
}
else
{
nc.WriteVar(xname, x.data());
nc.WriteVar(yname, y.data());
nc.WriteVar("type", t.data());
}
for(size_t ix = 0; ix < c; ix++) buf[ix] = x[ix];
ret = nc_put_vara_float(ncid, xid, &i, &c, buf);
if(ret != NC_NOERR) return "Can't write x variable in the netcdf file";
for(size_t ix = 0; ix < c; ix++) buf[ix] = y[ix];
ret = nc_put_vara_float(ncid, yid, &i, &c, buf);
if(ret != NC_NOERR) return "Can't write y variable in the netcdf file";
ret = nc_put_vara_ubyte(ncid, tid, &i, &c, t.data());
if(ret != NC_NOERR) return "Can't write type variable in the netcdf file";
ret = nc_close(ncid);
if(ret != NC_NOERR) return "Can't close netcdf file";
if(!nc) return MString("Can't write data to the netcdf file: ") + nc.ErrMessage();
return "";
}

197
actions/actionuv.h

@ -70,8 +70,6 @@ class UVMethods
std::vector<real> x, y;
std::vector<michlib::uint1> t;
bool lonlat;
NCFileWBase nc;
bool tdep;
size_t N() const { return t.size(); }
@ -88,19 +86,9 @@ class UVMethods
}
}
void Reset()
{
x.clear();
y.clear();
t.clear();
}
void WriteBinBile(const MString& name, const michlib_internal::ParameterListEx& pars) const;
MString CreateNcFile(const MString& name, const michlib_internal::ParameterListEx& pars, const MString& history, int comp, const TimeData& tdata, bool timedep);
MString WriteNcFile(size_t it);
void WriteBinBile(const MString& name) const;
void CloseNcFile() { nc.Close(); }
MString WriteNcFile(const MString& name, const MString& history, int comp) const;
};
};
@ -117,30 +105,10 @@ template<class D> MString ActionUV::DoAction(const CLArgs& args, D& ds)
michlib_internal::ParameterListEx pars;
pars.UsePrefix("");
pars.SetParameter("source", args.at("source"));
pars.SetParameter("history", args.at("_cmdline"));
VelSource mode = VelSource::AUTOSEL;
if(args.contains("geostrophic"))
{
auto modestr = args.at("geostrophic");
if(modestr == "" || modestr == "ssh")
mode = VelSource::GEOSTROPHICSSH;
else if(modestr == "surf" || modestr == "surface")
mode = VelSource::GEOSTROPHIC;
else if(modestr == "nongeo")
mode = VelSource::STANDART;
else
return "Parameter \"geostrophic\" have incorrect value " + modestr;
}
auto [tindexes, err] = GetTIndexes(ds, args, pars);
if(err.Exist()) return err;
bool average = args.contains("average");
int compress = 3;
if(args.contains("compress")) compress = args.at("compress").ToInt();
std::unique_ptr<const BaseParameters> sourcepars;
if constexpr(ParametersSupported<D>)
{
@ -159,40 +127,15 @@ template<class D> MString ActionUV::DoAction(const CLArgs& args, D& ds)
}
auto p = sourcepars.get();
TimeData tdata(ds, tindexes);
auto data = ReadUV(ds, p, tindexes);
if(!data) return "Can't read data";
// Main file
MString name = args.contains("out") ? args.at("out") : "";
MString outfmt = args.contains("outformat") ? args.at("outformat") : (GetExt(name) == "nc" ? "nc" : "bin");
MString namevel = args.contains("velout") ? args.at("velout") : "";
MString outfmtvel = args.contains("veloutformat") ? args.at("veloutformat") : (GetExt(namevel) == "nc" ? "nc" : "bin");
MString namestp = args.contains("stpout") ? args.at("stpout") : "";
MString outfmtstp = args.contains("stpoutformat") ? args.at("stpoutformat") : (GetExt(namestp) == "nc" ? "nc" : "bin");
size_t shiftx = args.contains("shiftx") ? args.at("shiftx").ToInteger<size_t>() : 0;
size_t shifty = args.contains("shifty") ? args.at("shifty").ToInteger<size_t>() : 0;
size_t skipx = args.contains("skipx") ? args.at("skipx").ToInteger<size_t>() : 1;
size_t skipy = args.contains("skipy") ? args.at("skipy").ToInteger<size_t>() : 1;
if(!average && tindexes.size() > 1 && ((name.Exist() && outfmt == "bin") || (namevel.Exist() && outfmtvel == "bin") || (namestp.Exist() && outfmtstp == "bin")))
return "Multiple time moments does'nt supported by the bin format";
bool headwrited = false;
MString velunit, distunit;
NCFileW fw, fwfilt;
MString u = data.Unit().Exist() ? data.Unit() : "unknown", d = data.DUnit().Exist() ? data.DUnit() : "unknown";
StPoints stp(true);
for(size_t it = 0; it < tindexes.size(); it++)
{
auto data = average ? ReadUV(ds, p, tindexes, mode) : ReadUV(ds, p, tindexes[it], mode);
if(!headwrited)
{
velunit = data.Unit().Exist() ? data.Unit() : "unknown";
distunit = data.DUnit().Exist() ? data.DUnit() : "unknown";
}
// Main file
if(name.Exist())
{
if(outfmt == "bin")
@ -201,13 +144,13 @@ template<class D> MString ActionUV::DoAction(const CLArgs& args, D& ds)
fw.Create(name, 9);
fw.SetColumnName(1, "Longitude");
fw.SetColumnName(2, "Latitude");
fw.SetColumnName(3, "u, " + velunit);
fw.SetColumnName(4, "v, " + velunit);
fw.SetColumnName(5, "Div, (" + velunit + ")/" + distunit);
fw.SetColumnName(6, "Rot, (" + velunit + ")/" + distunit);
fw.SetColumnName(7, "Okubo-Weiss parameter, (" + velunit + ")2/" + distunit + "2");
fw.SetColumnName(8, "Kinetic energy, (" + velunit + ")2");
fw.SetColumnName(9, "Eddy kinetic energy, (" + velunit + ")2");
fw.SetColumnName(3, "u, " + u);
fw.SetColumnName(4, "v, " + u);
fw.SetColumnName(5, "Div, (" + u + ")/" + d);
fw.SetColumnName(6, "Rot, (" + u + ")/" + d);
fw.SetColumnName(7, "Okubo-Weiss parameter, (" + u + ")2/" + d + "2");
fw.SetColumnName(8, "Kinetic energy, (" + u + ")2");
fw.SetColumnName(9, "Eddy kinetic energy, (" + u + ")2");
fw.SetParameters(pars);
for(size_t i = 0; i < data.N(); i++)
@ -227,48 +170,58 @@ template<class D> MString ActionUV::DoAction(const CLArgs& args, D& ds)
}
else if(outfmt == "nc" || outfmt == "netcdf")
{
int compress = 3;
NCFileW fw;
MString err;
if(!err.Exist() && !headwrited) err = fw.Create(data, name, compress);
if(!err.Exist() && !headwrited) err = fw.AddTimeData(tdata, !average);
if(!err.Exist() && !headwrited) err = fw.AddAtts(pars);
if(!err.Exist() && !headwrited) err = fw.AddVariable("u", "", "Eastward velocity", velunit, "");
if(!err.Exist() && !headwrited) err = fw.AddVariable("v", "", "Northward velocity", velunit, "");
if(!err.Exist() && !headwrited) err = fw.AddVariable("div", "", "Velocity divergence", "(" + velunit + ")/" + distunit, "");
if(!err.Exist() && !headwrited) err = fw.AddVariable("rot", "", "Velocity rotor", "(" + velunit + ")/" + distunit, "");
if(!err.Exist() && !headwrited) err = fw.AddVariable("ow", "", "Okubo-Weiss parameter", "(" + velunit + ")2/" + distunit + "2", "");
if(!err.Exist() && !headwrited) err = fw.AddVariable("ke", "", "Squared velocity module, u^2+v^2", "(" + velunit + ")2", "");
if(!err.Exist() && !headwrited) err = fw.AddVariable("eke", "", "Squared velocity dispersion aka eddy kinetic energy, <u^2+v^2>-<u>^2-<v>^2", "(" + velunit + ")2", "");
if(!err.Exist() && !headwrited) err = fw.WriteGrid(data);
if(!err.Exist()) err = fw.WriteVariable(data, "u", [&data = std::as_const(data)](size_t i, size_t j) { return data.U(i, j); }, it);
if(!err.Exist()) err = fw.WriteVariable(data, "v", [&data = std::as_const(data)](size_t i, size_t j) { return data.V(i, j); }, it);
if(!err.Exist()) err = fw.WriteVariable(data, "div", [&data = std::as_const(data)](size_t i, size_t j) { return data.Div(i, j); }, it);
if(!err.Exist()) err = fw.WriteVariable(data, "rot", [&data = std::as_const(data)](size_t i, size_t j) { return data.Rot(i, j); }, it);
if(!err.Exist()) err = fw.WriteVariable(data, "ow", [&data = std::as_const(data)](size_t i, size_t j) { return data.OW(i, j); }, it);
if(!err.Exist()) err = fw.WriteVariable(data, "ke", [&data = std::as_const(data)](size_t i, size_t j) { return data.U2(i, j); }, it);
if(args.contains("compress")) compress = args.at("compress").ToInt();
if(!err.Exist()) err = fw.Create(data, name, args.at("_cmdline"), compress);
if(!err.Exist()) err = fw.AddVariable("u", "", "Eastward velocity", u, "");
if(!err.Exist()) err = fw.AddVariable("v", "", "Northward velocity", u, "");
if(!err.Exist()) err = fw.AddVariable("div", "", "Velocity divergence", "(" + u + ")/" + d, "");
if(!err.Exist()) err = fw.AddVariable("rot", "", "Velocity rotor", "(" + u + ")/" + d, "");
if(!err.Exist()) err = fw.AddVariable("ow", "", "Okubo-Weiss parameter", "(" + u + ")2/" + d + "2", "");
if(!err.Exist()) err = fw.AddVariable("ke", "", "Squared velocity module, u^2+v^2", "(" + u + ")2", "");
if(!err.Exist()) err = fw.AddVariable("eke", "", "Squared velocity dispersion aka eddy kinetic energy, <u^2+v^2>-<u>^2-<v>^2", "(" + u + ")2", "");
if(!err.Exist()) err = fw.WriteGrid(data);
if(!err.Exist()) err = fw.WriteVariable(data, "u", [&data = std::as_const(data)](size_t i, size_t j) { return data.U(i, j); });
if(!err.Exist()) err = fw.WriteVariable(data, "v", [&data = std::as_const(data)](size_t i, size_t j) { return data.V(i, j); });
if(!err.Exist()) err = fw.WriteVariable(data, "div", [&data = std::as_const(data)](size_t i, size_t j) { return data.Div(i, j); });
if(!err.Exist()) err = fw.WriteVariable(data, "rot", [&data = std::as_const(data)](size_t i, size_t j) { return data.Rot(i, j); });
if(!err.Exist()) err = fw.WriteVariable(data, "ow", [&data = std::as_const(data)](size_t i, size_t j) { return data.OW(i, j); });
if(!err.Exist()) err = fw.WriteVariable(data, "ke", [&data = std::as_const(data)](size_t i, size_t j) { return data.U2(i, j); });
if(!err.Exist())
err = fw.WriteVariable(
data, "eke", [&data = std::as_const(data)](size_t i, size_t j) { return data.U2(i, j) - (data.U(i, j) * data.U(i, j) + data.V(i, j) * data.V(i, j)); }, it);
err = fw.WriteVariable(data, "eke", [&data = std::as_const(data)](size_t i, size_t j) { return data.U2(i, j) - (data.U(i, j) * data.U(i, j) + data.V(i, j) * data.V(i, j)); });
if(err.Exist()) return err;
fw.Close();
}
else
return "Unknown format: " + outfmt;
}
// Filtered file
if(namevel.Exist())
// Filtered vectors file
name = args.contains("velout") ? args.at("velout") : "";
outfmt = args.contains("veloutformat") ? args.at("veloutformat") : (GetExt(name) == "nc" ? "nc" : "bin");
if(name.Exist())
{
size_t shiftx = args.contains("shiftx") ? args.at("shiftx").ToInteger<size_t>() : 0;
size_t shifty = args.contains("shifty") ? args.at("shifty").ToInteger<size_t>() : 0;
size_t skipx = args.contains("skipx") ? args.at("skipx").ToInteger<size_t>() : 1;
size_t skipy = args.contains("skipy") ? args.at("skipy").ToInteger<size_t>() : 1;
Sparser<decltype(data)> sdata(data, shiftx, shifty, skipx, skipy);
if(outfmtvel == "bin")
if(outfmt == "bin")
{
BFileW vel;
vel.Create(namevel, 4);
vel.Create(name, 4);
vel.SetColumnName(1, "Longitude");
vel.SetColumnName(2, "Latitude");
vel.SetColumnName(3, "u, " + velunit);
vel.SetColumnName(4, "v, " + velunit);
vel.SetParameters(pars);
vel.SetColumnName(3, "u, " + u);
vel.SetColumnName(4, "v, " + u);
for(size_t ix = 0; ix < sdata.Nx(); ix++)
for(size_t iy = 0; iy < sdata.Ny(); iy++)
@ -281,50 +234,50 @@ template<class D> MString ActionUV::DoAction(const CLArgs& args, D& ds)
vel.Finalize();
vel.Close();
}
else if(outfmtvel == "nc" || outfmtvel == "netcdf")
else if(outfmt == "nc" || outfmt == "netcdf")
{
int compress = 3;
NCFileW fw;
MString err;
if(!err.Exist() && !headwrited) err = fwfilt.Create(sdata, namevel, compress);
if(!err.Exist() && !headwrited) err = fwfilt.AddTimeData(tdata, !average);
if(!err.Exist() && !headwrited) err = fwfilt.AddAtts(pars);
if(!err.Exist() && !headwrited) err = fwfilt.AddVariable("u", "", "Eastward velocity", velunit, "");
if(!err.Exist() && !headwrited) err = fwfilt.AddVariable("v", "", "Northward velocity", velunit, "");
if(!err.Exist() && !headwrited) err = fwfilt.WriteGrid(sdata);
if(args.contains("compress")) compress = args.at("compress").ToInt();
if(!err.Exist()) err = fw.Create(sdata, name, args.at("_cmdline"), compress);
if(!err.Exist()) err = fw.AddVariable("u", "", "Eastward velocity", u, "");
if(!err.Exist()) err = fw.AddVariable("v", "", "Northward velocity", u, "");
if(!err.Exist()) err = fw.WriteGrid(sdata);
if(!err.Exist()) err = fwfilt.WriteVariable(sdata, "u", [&data = std::as_const(sdata)](size_t i, size_t j) { return data.U(i, j); }, it);
if(!err.Exist()) err = fwfilt.WriteVariable(sdata, "v", [&data = std::as_const(sdata)](size_t i, size_t j) { return data.V(i, j); }, it);
if(!err.Exist()) err = fw.WriteVariable(sdata, "u", [&data = std::as_const(sdata)](size_t i, size_t j) { return data.U(i, j); });
if(!err.Exist()) err = fw.WriteVariable(sdata, "v", [&data = std::as_const(sdata)](size_t i, size_t j) { return data.V(i, j); });
if(err.Exist()) return err;
fw.Close();
}
else
return "Unknown format: " + outfmtvel;
return "Unknown format: " + outfmt;
}
// Stationary points
if(namestp.Exist())
name = args.contains("stpout") ? args.at("stpout") : "";
outfmt = args.contains("stpoutformat") ? args.at("stpoutformat") : (GetExt(name) == "nc" ? "nc" : "bin");
if(name.Exist())
{
stp.Reset();
StPoints p(true);
for(size_t ix = 0; ix < data.Nx() - 1; ix++)
for(size_t iy = 0; iy < data.Ny() - 1; iy++) stp.Add(data.StablePoints(ix, iy));
for(size_t iy = 0; iy < data.Ny() - 1; iy++) p.Add(data.StablePoints(ix, iy));
if(outfmtstp == "bin")
stp.WriteBinBile(namestp, pars);
else if(outfmtstp == "nc" || outfmtstp == "netcdf")
if(outfmt == "bin")
p.WriteBinBile(name);
else if(outfmt == "nc" || outfmt == "netcdf")
{
MString err;
if(!err.Exist() && !headwrited) err = stp.CreateNcFile(namestp, pars, args.at("_cmdline"), compress, tdata, !average);
if(!err.Exist()) err = stp.WriteNcFile(it);
int compress = args.contains("compress") ? args.at("compress").ToInt() : 3;
MString err = p.WriteNcFile(name, args.at("_cmdline"), compress);
if(err.Exist()) return err;
}
else
return "Unknown format: " + outfmt;
}
if(average) break;
headwrited = true;
}
fw.Close();
fwfilt.Close();
stp.CloseNcFile();
return "";
};

195
include/actiondep.h

@ -5,8 +5,6 @@
#include "mregex.h"
#include "traits.h"
#include "uvdata.h"
#include <array>
#include <utility>
using michlib::MDateTime;
@ -14,7 +12,7 @@ using michlib::MDateTime;
#define ADD_ACTION(actclass, actname, suptest, ...) ADD ACTION CLASS: actclass
#else
#define ADD_ACTION(actclass, actname, suptest, ...) \
class Action##actclass __VA_OPT__( : protected) __VA_ARGS__ \
class Action##actclass __VA_OPT__( : public) __VA_ARGS__ \
{ \
public: \
static constexpr const char* name = #actname; \
@ -23,49 +21,6 @@ using michlib::MDateTime;
};
#endif
enum class VelSource
{
AUTOSEL,
STANDART,
GEOSTROPHIC,
GEOSTROPHICSSH
};
struct TimeData
{
static constexpr auto stepunits = std::to_array<uint>({3600 * 24, 3600, 60, 1});
static constexpr std::array<const std::string, stepunits.size()> stepnames{"days", "hours", "minutes", "seconds"};
MDateTime refdate;
size_t unitind;
std::vector<michlib::int4> steps;
template<class D> TimeData(const D& data, const TIndex& tindexes): refdate(), unitind(stepunits.size()), steps(tindexes.size())
{
if(steps.size() == 0) return;
refdate = data.Time(tindexes[0]);
unitind = 0;
for(size_t i = 0; i < steps.size(); i++)
{
auto delta = data.Time(tindexes[i]) - refdate;
while(delta.Seconds() % stepunits[unitind] != 0) unitind++;
}
for(size_t i = 0; i < steps.size(); i++)
{
auto delta = data.Time(tindexes[i]) - refdate;
steps[i] = michlib::int_cast<decltype(steps)::value_type>(delta.Seconds() / stepunits[unitind]);
}
}
MString UnitName() const
{
MString out = stepnames[unitind].c_str();
return out + " since " + refdate.ToString();
}
};
template<class D> size_t GetTIndex(const D& data, const MDateTime& t)
{
size_t nt = data.NTimes();
@ -90,14 +45,10 @@ template<class D> std::pair<TIndex, MString> GetTIndexes(const D& data, const CL
MString regex = args.at("time");
MDateTime time;
if(time.FromString(regex)) // Time, not regex
tindexes.push_back(GetTIndex(data, time));
else if(regex == "BEGIN" || regex == "BEG" || regex == "FIRST") // First time
tindexes.push_back(0);
else if(regex == "END" || regex == "LAST") // Last time
tindexes.push_back(data.NTimes() - 1);
else // Regular expression
{
if(time.FromString(regex)) return {TIndex(1, GetTIndex(data, time)), ""}; // Time, not regex
if(regex == "BEGIN" || regex == "BEG" || regex == "FIRST") return {TIndex(1, 0), ""}; // First time
if(regex == "END" || regex == "LAST") return {TIndex(1, data.NTimes() - 1), ""}; // Last time
michlib::RegExpSimple reg(regex.Buf());
if(reg.Compile() != 0) return {tindexes, "Bad regular expression: " + regex};
@ -106,11 +57,9 @@ template<class D> std::pair<TIndex, MString> GetTIndexes(const D& data, const CL
MString date = data.Time(i).ToString();
if(reg.Match(date.Buf())) tindexes.push_back(i);
}
}
if(tindexes.size() == 0) return {tindexes, "There are no times matching the regular expression: " + regex};
if(tindexes.size() == 1)
pars.SetParameter("time", data.Time(tindexes[0]).ToTString());
pars.SetParameter("time", data.Time(tindexes[0]).ToString());
else
pars.SetParameter("timeregex", args.at("time"));
}
@ -130,23 +79,40 @@ template<class D> std::pair<TIndex, MString> GetTIndexes(const D& data, const CL
if(beg > data.Time(nt - 1)) return {tindexes, "Begin time " + b.ToTString() + " is greater then end time in the dataset " + data.Time(nt - 1).ToTString()};
if(end < data.Time(0)) return {tindexes, "End time " + e.ToTString() + " is lesser then begin time in the dataset " + data.Time(0).ToTString()};
size_t ib = 0, ie = nt - 1;
for(size_t i = 0; i < nt; i++)
if(data.Time(i) >= beg && data.Time(i) <= end) tindexes.push_back(i);
if(data.Time(i) >= beg)
{
ib = i;
break;
}
if(tindexes.size() == 0) return {tindexes, "There are no times between " + b.ToString() + " and " + e.ToString()};
pars.SetParameter("timeb", b.ToTString());
pars.SetParameter("timee", e.ToTString());
for(size_t i = nt; i != 0; i--)
if(data.Time(i - 1) <= end)
{
ie = i - 1;
break;
}
std::ranges::sort(tindexes, [&data = std::as_const(data)](size_t a, size_t b) { return data.Time(a) < data.Time(b); });
tindexes.resize(ie - ib + 1);
for(size_t i = 0; i < ie - ib + 1; i++) tindexes[i] = i + ib;
if(tindexes.size() == 0) return {tindexes, "There are no times between " + b.ToString() + " and " + e.ToString()};
pars.SetParameter("timeb", b.ToString());
pars.SetParameter("timee", e.ToString());
}
return {tindexes, ""};
}
template<class D> std::vector<ReadType<D>> Read(const D& data, const std::vector<MString>& vnames, const BaseParameters* p, size_t ind)
template<class D> std::vector<ReadType<D>> Read(const D& data, const std::vector<MString>& vnames, const BaseParameters* p, const TIndex& tindex)
{
using RT = ReadType<D>;
size_t ind;
std::vector<RT> out;
if(tindex.size() == 1)
{
ind = tindex[0];
michlib::message("Time: " + data.Time(ind).ToTString());
std::map<MString, RT> cache;
for(const auto& vname: vnames)
@ -159,17 +125,7 @@ template<class D> std::vector<ReadType<D>> Read(const D& data, const std::vector
if(!res) return out;
}
for(size_t i = 0; i < vnames.size(); i++) out.emplace_back(std::move(cache[vnames[i]]));
return out;
}
template<class D> std::vector<ReadType<D>> Read(const D& data, const std::vector<MString>& vnames, const BaseParameters* p, const TIndex& tindex)
{
using RT = ReadType<D>;
size_t ind;
std::vector<RT> out;
if(tindex.size() == 1)
return Read(data, vnames, p, tindex[0]);
}
else
{
std::vector<Averager<RT>> aver(vnames.size());
@ -195,102 +151,29 @@ template<class D> std::vector<ReadType<D>> Read(const D& data, const std::vector
return out;
}
template<class D> UVData<ReadType<D>> ReadUV(const D& data, const BaseParameters* p, size_t ind, VelSource usegeo)
template<class D> UVData<ReadType<D>> ReadUV(const D& data, const BaseParameters* p, size_t ind)
{
using RT = ReadType<D>;
using UV = UVData<RT>;
michlib::message("Time: " + data.Time(ind).ToTString());
std::map<MString, RT> cache;
bool res = false;
MString uname, vname;
switch(usegeo)
{
case(VelSource::AUTOSEL):
{
if(data.CheckVar("u") == VarPresence::INTERNAL && data.CheckVar("v") == VarPresence::INTERNAL)
{
uname = "u";
vname = "v";
}
else
{
uname = "ugs";
vname = "vgs";
}
break;
}
case(VelSource::STANDART):
{
uname = "u";
vname = "v";
break;
}
case(VelSource::GEOSTROPHIC):
{
uname = "ugs";
vname = "vgs";
break;
}
case(VelSource::GEOSTROPHICSSH):
{
uname = "ugeo";
vname = "vgeo";
break;
}
}
if constexpr(ReadPSupported<D>)
res = data.Read(uname, cache, p, ind) && data.Read(vname, cache, p, ind);
res = data.Read("u", cache, p, ind) && data.Read("v", cache, p, ind);
else if constexpr(ReadSupported<D>)
res = data.Read(uname, cache, ind) && data.Read(vname, cache, ind);
res = data.Read("u", cache, ind) && data.Read("v", cache, ind);
if(!res) return UV();
return UV(cache.at(uname), cache.at(vname));
return UV(cache.at("u"), cache.at("v"));
}
template<class D> UVData<ReadType<D>> ReadUV(const D& data, const BaseParameters* p, const TIndex& tindex, VelSource usegeo)
template<class D> UVData<ReadType<D>> ReadUV(const D& data, const BaseParameters* p, const TIndex& tindex)
{
using RT = ReadType<D>;
using UV = UVData<RT>;
MString uname, vname;
switch(usegeo)
{
case(VelSource::AUTOSEL):
{
if(data.CheckVar("u") == VarPresence::INTERNAL && data.CheckVar("v") == VarPresence::INTERNAL)
{
uname = "u";
vname = "v";
}
else
{
uname = "ugs";
vname = "vgs";
}
break;
}
case(VelSource::STANDART):
{
uname = "u";
vname = "v";
break;
}
case(VelSource::GEOSTROPHIC):
{
uname = "ugs";
vname = "vgs";
break;
}
case(VelSource::GEOSTROPHICSSH):
{
uname = "ugeo";
vname = "vgeo";
break;
}
}
if(tindex.size() == 1)
return ReadUV(data, p, tindex[0], usegeo);
return ReadUV(data, p, tindex[0]);
else
{
Averager<UV> out;
@ -304,12 +187,12 @@ template<class D> UVData<ReadType<D>> ReadUV(const D& data, const BaseParameters
std::map<MString, RT> cache;
bool res = false;
if constexpr(ReadPSupported<D>)
res = data.Read(uname, cache, p, ind) && data.Read(vname, cache, p, ind);
res = data.Read("u", cache, p, ind) && data.Read("v", cache, p, ind);
else if constexpr(ReadSupported<D>)
res = data.Read(uname, cache, ind) && data.Read(vname, cache, ind);
res = data.Read("u", cache, ind) && data.Read("v", cache, ind);
if(!res) return UV();
UV dat(cache.at(uname), cache.at(vname));
UV dat(cache.at("u"), cache.at("v"));
if(dat)
out.Add(std::move(dat));
else

18
include/basedata.h

@ -15,26 +15,12 @@ struct Region
real lonb, lone, latb, late;
};
struct GridPoint
{
size_t ix = 0, iy = 0;
real x = -1.0, y = -1.0;
bool Valid() const { return x >= 0.0 && y >= 0.0; }
};
struct Point2D
struct GridPointLocation
{
size_t ix, iy;
real x, y;
};
enum class VarPresence
{
NONE,
INTERNAL,
DERIVED
};
class BaseData
{
protected:

447
include/cache.h

@ -1,447 +0,0 @@
#pragma once
#include "GPL.h"
#include "mirrorfuncs.h"
#include <functional>
#include <libpq-fe.h>
#include <optional>
#include <sqlite3.h>
#include <time.h>
#include <variant>
using michlib::GPL;
using michlib::int1;
using michlib::int4;
using michlib::int_cast;
using michlib::MString;
using michlib::pointer_cast;
class SQLiteConnection
{
public:
using DBType = sqlite3*;
using FuncType = std::function<void(DBType)>;
private:
static DBType db;
static size_t count;
static std::vector<FuncType> destructs;
public:
SQLiteConnection()
{
count++;
if(db == nullptr)
{
MString oldprefix = GPL.UsePrefix("SQLITE");
MString name = GPL.ParameterSValue("db", "");
GPL.UsePrefix(oldprefix);
auto ret = sqlite3_open(name.Buf(), &db);
if(ret != SQLITE_OK)
{
sqlite3_close(db);
db = nullptr;
}
}
}
SQLiteConnection([[maybe_unused]] const SQLiteConnection& sq): SQLiteConnection() {}
SQLiteConnection(SQLiteConnection&&) = default;
SQLiteConnection& operator=([[maybe_unused]] const SQLiteConnection& sq)
{
*this = {};
return *this;
}
SQLiteConnection& operator=(SQLiteConnection&&) = default;
~SQLiteConnection()
{
if(count == 0) michlib::errmessage("Destructor of SQLiteConnection called on count==0");
if(count > 1)
count--;
else
{
count = 0;
if(db != nullptr)
{
for(const auto& f: destructs) f(db);
sqlite3_close(db);
}
db = nullptr;
}
}
static void AddDestructor(FuncType&& f) { destructs.emplace_back(std::move(f)); }
operator DBType() const { return db; }
static DBType GetDB() { return db; }
explicit operator bool() const { return db != nullptr; }
};
class PostgreSQLConnection
{
public:
using DBType = PGconn*;
using FuncType = std::function<void(DBType)>;
private:
static DBType conn;
static size_t count;
static std::vector<FuncType> destructs;
public:
PostgreSQLConnection()
{
count++;
if(conn == nullptr)
{
MString oldprefix = GPL.UsePrefix("POSTGRES");
MString name = GPL.ParameterSValue("connection", "");
GPL.UsePrefix(oldprefix);
conn = PQconnectdb(name.Buf());
if(PQstatus(conn) != CONNECTION_OK)
{
michlib::errmessage(PQerrorMessage(conn));
PQfinish(conn);
conn = nullptr;
}
}
}
PostgreSQLConnection([[maybe_unused]] const PostgreSQLConnection& pq): PostgreSQLConnection() {}
PostgreSQLConnection(PostgreSQLConnection&&) = default;
PostgreSQLConnection& operator=([[maybe_unused]] const PostgreSQLConnection& pq)
{
*this = {};
return *this;
}
PostgreSQLConnection& operator=(PostgreSQLConnection&&) = default;
~PostgreSQLConnection()
{
if(count == 0) michlib::errmessage("Destructor of PostgreSQLConnection called on count==0");
if(count > 1)
count--;
else
{
count = 0;
if(conn != nullptr)
{
for(const auto& f: destructs) f(conn);
PQfinish(conn);
}
conn = nullptr;
}
}
static void AddDestructor(FuncType&& f) { destructs.emplace_back(std::move(f)); }
operator DBType() const { return conn; }
static DBType GetDB() { return conn; }
explicit operator bool() const { return conn != nullptr; }
};
class GenericCache
{
public:
virtual bool Put(const MString& key, const MString& value, size_t ttl) const = 0;
virtual std::pair<MString, bool> Get(const MString& key) const = 0;
virtual ~GenericCache() {}
};
class FakeCache: public GenericCache
{
public:
virtual bool Put([[maybe_unused]] const MString& key, [[maybe_unused]] const MString& value, [[maybe_unused]] size_t ttl) const override { return false; }
virtual std::pair<MString, bool> Get([[maybe_unused]] const MString& key) const override { return {"", false}; }
virtual ~FakeCache() override {}
};
class SQLiteCache: public GenericCache
{
static bool regdest;
SQLiteConnection db;
public:
bool Init()
{
if(!db) return false;
if(!regdest)
{
// Create table
sqlite3_stmt* sqst;
int i;
i = sqlite3_prepare_v2(db,
"CREATE TABLE IF NOT EXISTS `cache`('key' TEXT PRIMARY KEY ON CONFLICT REPLACE NOT NULL ON CONFLICT FAIL, 'value' BLOB NOT NULL ON CONFLICT FAIL, "
"'exptime' INTEGER NOT NULL ON CONFLICT FAIL) WITHOUT ROWID, STRICT;",
-1, &sqst, 0);
i = sqlite3_step(sqst);
if(i != SQLITE_DONE)
{
sqlite3_finalize(sqst);
return false;
}
sqlite3_finalize(sqst);
sqlite3_busy_timeout(db, 1000);
db.AddDestructor(
[](SQLiteConnection::DBType db)
{
sqlite3_stmt* sqst = nullptr;
int i = SQLITE_OK;
if(i == SQLITE_OK) i = sqlite3_prepare_v2(db, "DELETE from `cache` WHERE exptime<?1;", -1, &sqst, 0);
if(i == SQLITE_OK) i = sqlite3_bind_int64(sqst, 1, time(nullptr));
if(i == SQLITE_OK) i = sqlite3_step(sqst);
sqlite3_finalize(sqst);
});
regdest = true;
}
return true;
}
virtual bool Put(const MString& key, const MString& value, size_t ttl) const override
{
if(!*this) return false;
sqlite3_stmt* sqst = nullptr;
int i = SQLITE_OK;
if(i == SQLITE_OK) i = sqlite3_prepare_v2(db, "INSERT OR REPLACE into `cache` VALUES(?1,?2,?3);", -1, &sqst, 0);
if(i == SQLITE_OK) i = sqlite3_bind_text(sqst, 1, key.Buf(), -1, SQLITE_STATIC);
if(i == SQLITE_OK) i = sqlite3_bind_blob64(sqst, 2, value.Buf(), value.Len(), SQLITE_STATIC);
if(i == SQLITE_OK) i = sqlite3_bind_int64(sqst, 3, time(nullptr) + ttl);
if(i == SQLITE_OK) i = sqlite3_step(sqst);
sqlite3_finalize(sqst);
return i == SQLITE_OK;
}
virtual std::pair<MString, bool> Get(const MString& key) const override
{
if(!*this) return {"", false};
sqlite3_stmt* sqst = nullptr;
int i = SQLITE_OK;
if(i == SQLITE_OK) i = sqlite3_prepare_v2(db, "SELECT value from `cache` WHERE key=?1 AND exptime>?2;", -1, &sqst, 0);
if(i == SQLITE_OK) i = sqlite3_bind_text(sqst, 1, key.Buf(), -1, SQLITE_STATIC);
if(i == SQLITE_OK) i = sqlite3_bind_int64(sqst, 2, time(nullptr));
if(i == SQLITE_OK) i = sqlite3_step(sqst);
if(i == SQLITE_ROW)
{
auto p = sqlite3_column_blob(sqst, 0);
auto sz = sqlite3_column_bytes(sqst, 0);
if(p != nullptr)
{
MString out(p, sz);
sqlite3_finalize(sqst);
return {std::move(out), true};
}
}
sqlite3_finalize(sqst);
return {"", false};
}
virtual ~SQLiteCache() override = default;
explicit operator bool() const { return db != nullptr; }
};
class PostgreSQLHelpers
{
static constexpr time_t postgresepoch = 946648800;
class PGResultRAIIDT
{
public:
// TODO: make static
void operator()(PGresult* res) { PQclear(res); }
};
protected:
PostgreSQLConnection conn;
// Convert Postgres binary representation of timestamp to Unix epoch seconds. Microseconds ignored
static time_t raw2epoch(time_t raw) { return Invert(raw) / 1000000 + postgresepoch; }
// Convert Unix epoch time to Postres binary representation
static time_t epoch2raw(time_t epoch) { return Invert((epoch - postgresepoch) * 1000000); }
class PGresultRAII: public std::unique_ptr<PGresult, PGResultRAIIDT>
{
public:
PGresultRAII() = default;
PGresultRAII(PGresult* res): std::unique_ptr<PGresult, PGResultRAIIDT>(res) {}
operator PGresult*() const { return get(); }
};
bool CheckCon() const
{
if(!*this) return false;
if(PQstatus(conn) == CONNECTION_OK) return true;
PQreset(conn);
return PQstatus(conn) == CONNECTION_OK;
}
template<class D> static D Invert(D d)
{
using michlib::int1;
D out;
Invert(&d, &out, sizeof(D));
return out;
}
static void Invert(const void* src, void* dst, size_t sz)
{
if(sz == 0) return;
const int1* pin = pointer_cast<const int1*>(src);
int1* pout = pointer_cast<int1*>(dst);
for(size_t i = 0; i < sz; i++) pout[sz - i - 1] = pin[i];
}
public:
explicit operator bool() const { return conn != nullptr; }
};
class PostgreSQLCache: public GenericCache, public PostgreSQLHelpers
{
static bool regdest;
public:
bool Init()
{
if(!conn) return false;
if(!regdest)
{
PGresultRAII res;
// Create table
res = PQexec(conn, "SET client_min_messages=WARNING;");
res = PQexec(conn, "CREATE TABLE IF NOT EXISTS cache(key TEXT PRIMARY KEY NOT NULL, value BYTEA, exptime TIMESTAMP(0) NOT NULL);");
if(PQresultStatus(res) != PGRES_COMMAND_OK)
{
michlib::errmessage(PQresStatus(PQresultStatus(res)));
michlib::errmessage(PQerrorMessage(conn));
}
res = PQexec(conn, "SET client_min_messages=NOTICE;");
conn.AddDestructor([](PostgreSQLConnection::DBType conn) { PGresultRAII res = PQexec(conn, "DELETE FROM cache WHERE exptime<localtimestamp;"); });
regdest = true;
}
return true;
}
virtual bool Put(const MString& key, const MString& value, size_t ttl) const override
{
if(!CheckCon()) return false;
auto interval = michlib::int_cast<michlib::int8>(ttl);
michlib::int8 rinterval = Invert(interval);
const char* params[] = {key.Buf(), value.Buf(), pointer_cast<const char*>(&rinterval)};
int plens[] = {int_cast<int>(key.Len()), int_cast<int>(value.Len()), sizeof(rinterval)};
int pfor[] = {0, 1, 1};
PGresultRAII res = PQexecParams(conn,
"INSERT INTO cache(key,value,exptime) VALUES($1,$2,localtimestamp + ($3::bigint ||' seconds')::interval)"
"ON CONFLICT(key) DO UPDATE SET value=EXCLUDED.value, exptime=EXCLUDED.exptime;",
3, nullptr, params, plens, pfor, 1);
if(PQresultStatus(res) != PGRES_COMMAND_OK)
{
michlib::errmessage(PQresStatus(PQresultStatus(res)));
michlib::errmessage(PQerrorMessage(conn));
return false;
}
return true;
}
virtual std::pair<MString, bool> Get(const MString& key) const override
{
if(!CheckCon()) return {"", false};
const char* params[] = {key.Buf()};
int plens[] = {int_cast<int>(key.Len())};
int pfor[] = {0};
PGresultRAII res = PQexecParams(conn, "SELECT value from cache WHERE key=$1::text AND exptime>localtimestamp;", 1, nullptr, params, plens, pfor, 1);
if(PQresultStatus(res) != PGRES_TUPLES_OK)
{
michlib::errmessage(PQresStatus(PQresultStatus(res)));
michlib::errmessage(PQerrorMessage(conn));
return {"", false};
}
else if(PQntuples(res) == 0)
return {"", false};
MString val(PQgetvalue(res, 0, 0), PQgetlength(res, 0, 0));
return {std::move(val), true};
}
virtual ~PostgreSQLCache() override = default;
};
inline GenericCache* CreateCache(const MString& cachedesc)
{
auto i = cachedesc.GetPos(':');
auto name = i == 0 ? cachedesc : cachedesc.SubStr(1, i - 1);
auto par = i == 0 ? "" : cachedesc.SubStr(i + 1, cachedesc.Len() - i);
if(name == "no") return new FakeCache;
if(name == "sqlite")
{
auto ret = new SQLiteCache;
ret->Init();
if(*ret) return ret;
delete ret;
}
if(name == "postgre" || name == "postgres" || name == "postgresql")
{
auto ret = new PostgreSQLCache;
ret->Init();
if(*ret) return ret;
delete ret;
}
return nullptr;
}
class FileInfoCache: public PostgreSQLHelpers
{
public:
using DataType = std::optional<MString>;
using CallbackType = std::function<DataType(const MString&)>;
private:
static bool regdest;
CallbackType readfunc;
MString dir;
int4 dirid;
FileInfoCache() = delete;
CallbackType::result_type GetData(const MString& fname) const { return readfunc(dir + "/" + fname); }
void GetDirId();
public:
FileInfoCache(CallbackType&& readfunc_, const MString& dir_);
Error UpdateCache(bool force = false) const;
DataType GetInfo(const MString& name) const;
};

54
include/copcat.h

@ -1,54 +0,0 @@
#pragma once
#include "cache.h"
#include "curlfuncs.h"
#include "merrors.h"
#include <json/json.h>
using michlib::Error;
using michlib::RetVal;
class CopernicusCatalog
{
static const MString caturl;
std::unique_ptr<GenericCache> cache;
CURLRAII chandle;
Json::Value catalog;
// Download catalog
Error GetCatalog();
// Asset url from dataset
RetVal<MString> AssetURL(const MString& prod, const MString& dataset, const MString& asset) const;
public:
CopernicusCatalog();
// Download JSON from url
RetVal<Json::Value> GetJSON(const MString& url) const;
// List of products
RetVal<std::vector<MString>> ProductList() const;
// List of datasets in product
RetVal<std::vector<MString>> DatasetList(const MString& prod) const;
// URL of product
RetVal<MString> ProductURL(const MString& prod) const;
// URL of dataset
RetVal<MString> DatasetURL(const MString& prod, const MString& dataset) const;
// URL of native data (files) in dataset
RetVal<MString> DatasetNativeURL(const MString& prod, const MString& dataset) const { return AssetURL(prod, dataset, "native"); }
// URL of timechuncked data (files) in dataset
RetVal<MString> DatasetTimeURL(const MString& prod, const MString& dataset) const { return AssetURL(prod, dataset, "timeChunked"); }
// URL of geochuncked data (files) in dataset
RetVal<MString> DatasetGeoURL(const MString& prod, const MString& dataset) const { return AssetURL(prod, dataset, "geoChunked"); }
bool Valid() const { return catalog.isObject(); }
explicit operator bool() const { return Valid(); }
};

36
include/curlfuncs.h

@ -1,36 +0,0 @@
#pragma once
#include "MString.h"
#include <curl/curl.h>
#include <memory>
using michlib::MString;
class CURLRAIIDT
{
public:
// TODO: make static
void operator()(CURL* c) { curl_easy_cleanup(c); }
};
class CURLRAII: public std::unique_ptr<CURL, CURLRAIIDT>
{
char err[CURL_ERROR_SIZE];
public:
CURLRAII()
{
reset(curl_easy_init());
curl_easy_setopt(*this, CURLOPT_ERRORBUFFER, err);
}
operator CURL*() const { return get(); }
const char* Err() const { return err; }
};
// Curl writeback function, write to MString
size_t Write2String(char* ptr, size_t size, size_t n, void* data);
// Curl writeback function, write to file descriptor
size_t Write2File(char* ptr, size_t size, size_t n, void* data);
// Get content of url to MString
std::pair<MString, CURLcode> GetUrl(const CURLRAII& chandle, const MString& url);

51
include/interpolation.h

@ -1,51 +0,0 @@
#pragma once
#include "basedata.h"
#include "comdefs.h"
using michlib::real;
template<class D> class LinearInterpolator: public D
{
public:
LinearInterpolator(D&& d): D(std::move(d)) {}
real operator()(const struct Point2D& in) const
{
const auto gp = D::GridPos(in.x, in.y);
if(!gp.Valid()) return NAN;
if(gp.x == 0.0 && gp.y == 0.0) return D::V(gp.ix, gp.iy);
real v00;
real v10;
real v01;
real v11;
bool isfill = false;
size_t fx, fy;
// Count fills
for(size_t ix = 0; ix <= 1; ix++)
for(size_t iy = 0; iy <= 1; iy++)
{
if(isfill && D::IsFill(gp.ix + ix, gp.iy + iy)) return NAN;
if(D::IsFill(gp.ix + ix, gp.iy + iy))
{
fx = ix;
fy = iy;
isfill = true;
}
}
v00 = D::V(gp.ix, gp.iy);
v10 = D::V(gp.ix + 1, gp.iy);
v01 = D::V(gp.ix, gp.iy + 1);
v11 = D::V(gp.ix + 1, gp.iy + 1);
if(isfill && fx == 0 && fy == 0) v00 = (v10 + v01 + v11) / 3.0;
if(isfill && fx == 1 && fy == 0) v10 = (v00 + v01 + v11) / 3.0;
if(isfill && fx == 0 && fy == 1) v01 = (v10 + v00 + v11) / 3.0;
if(isfill && fx == 1 && fy == 1) v11 = (v10 + v01 + v00) / 3.0;
return v00 + gp.y * (v01 - v00) + gp.x * ((v10 - v00) + gp.y * (v00 - v01 + v11 - v10));
};
};

11
include/layereddata.h

@ -56,7 +56,6 @@ class LayeredData: public NCFuncs
const NCFileA& Get() const { return nc; }
const std::vector<MDateTime>& Times() const { return times; }
size_t Index(MDateTime tm) const
{
if(tm < Begin() || tm > End()) return 0;
@ -74,13 +73,11 @@ class LayeredData: public NCFuncs
}
return 0;
}
const MString& Url() const { return url; }
};
std::vector<NC> nc;
std::vector<real> depths;
std::vector<MDateTime> times;
struct DimNames dname;
struct CoordNames dname;
real lonb, latb, lone, late;
real lonstep, latstep;
MString title;
@ -146,8 +143,6 @@ class LayeredData: public NCFuncs
real Depth(size_t l) const { return isOk() ? depths[l] : -1000.0; }
real Depth(const BaseParameters* ip) const { return Depth(dynamic_cast<const struct Parameters*>(ip)->layer); }
real Lon(size_t ix) const { return isOk() ? (lonb + ix * lonstep) : -1000.0; }
real Lat(size_t iy) const { return isOk() ? (latb + iy * latstep) : -1000.0; }
@ -162,7 +157,7 @@ class LayeredData: public NCFuncs
return times[i];
}
time_t Timestep() const { return isOk() ? (times[1] - times[0]).Seconds() : 0; }
time_t Timestep() const { return isOk() ? (times[1] - times[0]) : 0; }
MString Title() const { return title; }
@ -177,7 +172,7 @@ class LayeredData: public NCFuncs
// clang-format on
}
VarPresence CheckVar(const MString& vname) const
bool CheckVar(const MString& vname) const
{
return NCFuncs::CheckVar(vname, [this](const MString& vn) { return HaveVar(vn); });
}

207
include/layereddataz.h

@ -1,207 +0,0 @@
#pragma once
#include "gsw.h"
#include "ncfuncs.h"
#include "nczarr.h"
#include "simple2ddata.h"
#include <memory>
using michlib::Ceil;
using michlib::DetGeoDomain;
using michlib::Floor;
using michlib::GPL;
using michlib::int2;
class LayeredDataZ: public NCFuncs
{
public:
using Data = Simple2DData;
private:
class NC: public NCZarr
{
std::vector<MDateTime> times;
public:
Error ReadTimes(const MString& tname)
{
static const MString pref = "LayeredDataZ::NC::ReadTimes";
if(!*this) return Error(pref, "Dataset not open");
std::vector<double> time;
{
auto ret = Read(tname, time);
if(!ret) return ret.Add(pref, "Can't read time");
}
MDateTime refdate;
time_t step = 0;
{
auto units = AttString(tname, "units");
if(!units.Exist()) return Error(pref, "Can't read refdate");
auto [rd, st, suc] = Refdate(units);
if(!suc) return Error(pref, "Can't parse " + units + " to refdate");
if(st == 0) return Error(pref, "Can't get timestep from string " + units);
refdate = rd;
step = st;
}
times.resize(time.size());
for(size_t i = 0; i < time.size(); i++) times[i] = refdate + static_cast<time_t>(time[i] * step);
return Error();
}
MDateTime Begin() const { return times.front(); }
MDateTime End() const { return times.back(); }
const std::vector<MDateTime>& Times() const { return times; }
size_t Index(MDateTime tm) const
{
if(tm < Begin() || tm > End()) return 0;
size_t b = 0, e = times.size() - 1;
if(tm == times[b]) return b + 1;
if(tm == times[e]) return e + 1;
while(e - b > 1)
{
size_t c = (e + b) / 2;
if(tm == times[c]) return c + 1;
if(tm > times[c])
b = c;
else
e = c;
}
return 0;
}
};
std::vector<NC> nc;
std::vector<real> depths;
bool depthinv;
std::vector<MDateTime> times;
struct DimNames dname;
real lonb, latb, lone, late;
real lonstep, latstep;
MString title;
class EnvVar
{
MString name, oldvalue;
bool activated, saved;
public:
EnvVar(): activated(false) {}
~EnvVar() { Deactivate(); }
void Activate(const MString& var, const MString& val)
{
if(activated) Deactivate();
name = var;
char* curval = getenv(name.Buf());
if(nullptr == curval)
saved = false;
else
{
oldvalue = curval;
saved = true;
}
setenv(name.Buf(), val.Buf(), 1);
}
void Deactivate()
{
if(!activated) return;
if(saved)
setenv(name.Buf(), oldvalue.Buf(), 1);
else
unsetenv(name.Buf());
activated = false;
}
};
EnvVar proxy;
protected:
struct Parameters: public BaseParameters
{
size_t xb, yb, xe, ye, layer;
virtual ~Parameters() override = default;
};
// TODO: RetVal
MString Open(const MString& dataset);
void SetTitle(const MString& newtitle) { title = newtitle; }
public:
MString Info() const;
std::pair<const BaseParameters*, MString> Parameters(michlib_internal::ParameterListEx& pars, const CLArgs& args, const struct Region& reg) const;
bool Read(const MString& vname, std::map<MString, Data>& cache, const BaseParameters* ip, size_t i) const;
bool isOk() const { return nc.size() > 0; }
explicit operator bool() const { return nc.size() > 0; }
real Depth(size_t l) const { return isOk() ? depths[l] : -1000.0; }
real Depth(const BaseParameters* ip) const { return Depth(dynamic_cast<const struct Parameters*>(ip)->layer); }
real Lon(size_t ix) const { return isOk() ? (lonb + ix * lonstep) : -1000.0; }
real Lat(size_t iy) const { return isOk() ? (latb + iy * latstep) : -1000.0; }
size_t NDepths() const { return depths.size(); }
size_t NTimes() const { return times.size(); }
MDateTime Time(size_t i) const
{
if(!isOk() || i >= times.size()) return MDateTime();
return times[i];
}
time_t Timestep() const { return isOk() ? (times[1] - times[0]).Seconds() : 0; }
MString Title() const { return title; }
MString Dump(const struct Parameters* ppar) const
{
// clang-format off
return
"Current settings:\n" + MString() +
" Longitudes: from " + Lon(ppar->xb) + " (" + ppar->xb + ") to "+ Lon(ppar->xe) + " (" + ppar->xe + ")\n" +
" Latitudes: from " + Lat(ppar->yb) + " (" + ppar->yb + ") to "+ Lat(ppar->ye) + " (" + ppar->ye + ")\n" +
" Depth: layer " + ppar->layer + ", depth " + Depth(ppar->layer) + " m\n";
// clang-format on
}
VarPresence CheckVar(const MString& vname) const
{
return NCFuncs::CheckVar(vname, [this](const MString& vn) { return HaveVar(vn); });
}
private:
Data ReadVarRaw(const NC& f, const MString& name, size_t i, bool nodepth, const struct Parameters* p) const;
bool HaveVar(const MString& vname) const
{
for(size_t i = 0; i < nc.size(); i++)
if(NCFuncs::HaveVar(nc[i], vname)) return true;
return false;
}
std::tuple<MString, size_t, size_t> VarNameLoc(const MString vname, MDateTime tm) const
{
for(size_t i = 0; i < nc.size(); i++)
{
auto tind = nc[i].Index(tm);
if(tind == 0) continue;
for(const auto& v: nc[i].VarNames())
{
auto stname = nc[i].AttString(v, "standard_name");
if(!stname.Exist()) continue;
if(StName2Name(stname) == vname) return {v, i, tind - 1};
}
}
return {"", 0, 0};
}
};

64
include/mirrorfuncs.h

@ -1,64 +0,0 @@
#pragma once
#include "curlfuncs.h"
#include "mdatetime.h"
#include <dirent.h>
#include <fcntl.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <vector>
using michlib::Error;
using michlib::MDateTime;
using michlib::RetVal;
class DIRRAIIDT
{
public:
// TODO: make static
void operator()(DIR* d) { closedir(d); }
};
class DIRRAII: public std::unique_ptr<DIR, DIRRAIIDT>
{
public:
operator DIR*() const { return get(); }
};
struct FileInfo
{
MString url;
MString name;
MDateTime mtime;
size_t size;
};
// Remove last element from path
inline MString DirName(const MString& name)
{
auto p = name.GetPos('/', false);
if(p == 0) return name;
return name.SubStr(1, p - 1);
}
// Get last element from path
inline MString FileName(const MString& name)
{
auto p = name.GetPos('/', false);
if(p == 0) return name;
return name.SubStr(p + 1, name.Len() - p);
}
// Check and, if necessary, create the path to the file
bool MakePath(const MString& dname);
// Get local file list
RetVal<std::vector<struct FileInfo>> ReadLocalFileList(const MString& dir, const bool nofollow = true, const MString& path = "");
// Download file to the local mirror
Error DownloadFile(const CURLRAII& chandle, const struct FileInfo& rinfo, const MString& root);
// Remove file from the local mirror
Error RemoveFile(const struct FileInfo& linfo);
// Updare file in the local mirror
Error UpdateFile(const CURLRAII& chandle, const struct FileInfo& rinfo, const struct FileInfo& linfo, const MString& root);

547
include/ncfilew.h

@ -1,6 +1,5 @@
#pragma once
#include "MString.h"
#include "actiondep.h"
#include "traits.h"
#include <algorithm>
#include <netcdf.h>
@ -9,456 +8,137 @@
using michlib::MString;
class NCFileWBase
class NCFileW
{
template<class T, class Dummy> struct NCTypeD
{
static constexpr nc_type nc = NC_NAT;
};
template<class Dummy> struct NCTypeD<michlib::int1, Dummy>
{
static constexpr nc_type nc = NC_BYTE;
};
template<class Dummy> struct NCTypeD<michlib::uint1, Dummy>
{
static constexpr nc_type nc = NC_UBYTE;
static int put_var(int nc, int vid, const michlib::uint1* data) { return nc_put_var_ubyte(nc, vid, data); }
static int put_vara(int nc, int vid, const size_t* startp, const size_t* countp, const michlib::uint1* data) { return nc_put_vara_ubyte(nc, vid, startp, countp, data); }
};
template<class Dummy> struct NCTypeD<michlib::int2, Dummy>
{
static constexpr nc_type nc = NC_SHORT;
static int put_var(int nc, int vid, const michlib::int2* data) { return nc_put_var_short(nc, vid, data); }
static int put_vara(int nc, int vid, const size_t* startp, const size_t* countp, const michlib::int2* data) { return nc_put_vara_short(nc, vid, startp, countp, data); }
};
template<class Dummy> struct NCTypeD<michlib::uint2, Dummy>
{
static constexpr nc_type nc = NC_USHORT;
static int put_var(int nc, int vid, const michlib::uint2* data) { return nc_put_var_ushort(nc, vid, data); }
static int put_vara(int nc, int vid, const size_t* startp, const size_t* countp, const michlib::uint2* data) { return nc_put_vara_ushort(nc, vid, startp, countp, data); }
};
template<class Dummy> struct NCTypeD<michlib::int4, Dummy>
{
static constexpr nc_type nc = NC_INT;
static int put_var(int nc, int vid, const michlib::int4* data) { return nc_put_var_int(nc, vid, data); }
static int put_vara(int nc, int vid, const size_t* startp, const size_t* countp, const michlib::int4* data) { return nc_put_vara_int(nc, vid, startp, countp, data); }
};
template<class Dummy> struct NCTypeD<michlib::uint4, Dummy>
{
static constexpr nc_type nc = NC_UINT;
static int put_var(int nc, int vid, const michlib::uint4* data) { return nc_put_var_uint(nc, vid, data); }
static int put_vara(int nc, int vid, const size_t* startp, const size_t* countp, const michlib::uint4* data) { return nc_put_vara_uint(nc, vid, startp, countp, data); }
};
template<class Dummy> struct NCTypeD<michlib::int8, Dummy>
{
static constexpr nc_type nc = NC_INT64;
};
template<class Dummy> struct NCTypeD<michlib::uint8, Dummy>
{
static constexpr nc_type nc = NC_UINT64;
};
template<class Dummy> struct NCTypeD<float, Dummy>
{
static constexpr nc_type nc = NC_FLOAT;
static int put_var(int nc, int vid, const float* data) { return nc_put_var_float(nc, vid, data); }
static int put_vara(int nc, int vid, const size_t* startp, const size_t* countp, const float* data) { return nc_put_vara_float(nc, vid, startp, countp, data); }
};
template<class Dummy> struct NCTypeD<double, Dummy>
{
static constexpr nc_type nc = NC_DOUBLE;
static int put_var(int nc, int vid, const double* data) { return nc_put_var_double(nc, vid, data); }
static int put_vara(int nc, int vid, const size_t* startp, const size_t* countp, const double* data) { return nc_put_vara_double(nc, vid, startp, countp, data); }
};
template<class Dummy> struct NCTypeD<MString, Dummy>
{
static constexpr nc_type nc = NC_CHAR;
};
template<class Dummy> struct NCTypeD<char*, Dummy>
enum Type
{
static constexpr nc_type nc = NC_CHAR;
UNKNOWN,
G1V1,
G1V2,
G2V2
};
template<class T> using NCType = NCTypeD<T, void>;
public:
template<class T> static constexpr nc_type Type2NCType = NCType<T>::nc;
// Error class
class Error
struct Var
{
int err;
public:
constexpr Error(): err(NC_NOERR) {}
constexpr Error(int n_err): err(n_err) {}
explicit operator bool() const { return err == NC_NOERR; }
const char* ErrMessage() const { return nc_strerror(err); }
int Err() const { return err; }
bool IsErr() const { return err != NC_NOERR; }
void Reset() { err = NC_NOERR; }
void Reset(int n_err) { err = n_err; }
void Reset(const Error& e) { err = e.err; }
MString name;
int id;
};
~NCFileWBase() { Close(); }
int Id() const { return ncid; }
int Err() const { return err.Err(); }
const char* ErrMessage() const { return err.ErrMessage(); }
explicit operator bool() const { return Ok(); }
bool Ok() const { return opened && !err.IsErr(); }
operator int() const { return ncid; }
void Close()
{
if(opened) nc_close(ncid);
err.Reset();
opened = false;
}
void Open(const MString& path)
{
if(opened) return;
err.Reset(nc_create(path.Buf(), NC_CLOBBER | NC_NETCDF4, &ncid));
opened = !err.IsErr();
}
void AddDim(const MString& name, size_t len)
{
if(err.IsErr()) return;
static int dimid;
err.Reset(nc_def_dim(ncid, name.Buf(), len, &dimid));
}
MString AddAtts(const michlib_internal::ParameterListEx& pars)
{
for(const auto& p: pars.GetParameterList())
{
MString ret;
if(p.first.Prefix() != "") continue; // Only parameters with empty prefix considered for now
switch(p.second.valtype)
{
case michlib_internal::Parameter::UINT1:
{
ret = AddAtt(p.first.Name(), p.second.value.u1);
break;
}
case michlib_internal::Parameter::UINT2:
{
ret = AddAtt(p.first.Name(), p.second.value.u2);
break;
}
case michlib_internal::Parameter::UINT4:
{
ret = AddAtt(p.first.Name(), p.second.value.u4);
break;
}
case michlib_internal::Parameter::UINT8:
{
ret = AddAtt(p.first.Name(), p.second.value.u8);
break;
}
case michlib_internal::Parameter::INT1:
{
ret = AddAtt(p.first.Name(), p.second.value.i1);
break;
}
case michlib_internal::Parameter::INT2:
{
ret = AddAtt(p.first.Name(), p.second.value.i2);
break;
}
case michlib_internal::Parameter::INT4:
{
ret = AddAtt(p.first.Name(), p.second.value.i4);
break;
}
case michlib_internal::Parameter::INT8:
{
ret = AddAtt(p.first.Name(), p.second.value.i8);
break;
}
case michlib_internal::Parameter::FLOAT:
{
ret = AddAtt(p.first.Name(), p.second.value.r4);
break;
}
case michlib_internal::Parameter::DOUBLE:
{
ret = AddAtt(p.first.Name(), p.second.value.r8);
break;
}
case michlib_internal::Parameter::LDOUBLE:
{
ret = AddAtt(p.first.Name(), static_cast<double>(p.second.value.r10));
break;
}
case michlib_internal::Parameter::BOOL:
{
ret = AddAtt(p.first.Name(), p.second.value.b ? 1 : 0);
break;
}
case michlib_internal::Parameter::STRING:
{
ret = AddAtt(p.first.Name(), p.second.svalue);
break;
}
case michlib_internal::Parameter::INVALID: break; // Silently skip
}
if(ret.Exist()) return ret;
}
return "";
}
template<class T>
requires(Type2NCType<T> != NC_NAT)
MString AddAtt(const MString& name, const T& val)
{
if(err.IsErr()) return "Can't write attribute " + name + " due to previous errors";
static constexpr auto nct = Type2NCType<T>;
static constexpr bool ischar = std::is_same_v<T, char*>;
if constexpr(nct != NC_CHAR)
err.Reset(nc_put_att(ncid, NC_GLOBAL, name.Buf(), nct, 1, &val));
else if constexpr(ischar)
err.Reset(nc_put_att_text(ncid, NC_GLOBAL, name.Buf(), strlen(val) + 1, val));
else
err.Reset(nc_put_att_text(ncid, NC_GLOBAL, name.Buf(), val.Len() + 1, val.Buf()));
return err.IsErr() ? "Can't write attribute " + name + ": " + ErrMessage() : "";
}
template<class T>
requires(Type2NCType<T> != NC_NAT)
MString AddAtt(const MString& vname, const MString& name, const T& val)
{
if(err.IsErr()) return "Can't write attribute " + name + " to the variable " + vname + " due to previous errors";
static constexpr auto nct = Type2NCType<T>;
static constexpr bool ischar = std::is_same_v<T, char*>;
int varid;
err.Reset(nc_inq_varid(ncid, vname.Buf(), &varid));
if(err.IsErr()) return "Can't find variable " + vname + ": " + ErrMessage();
if constexpr(nct != NC_CHAR)
err.Reset(nc_put_att(ncid, varid, name.Buf(), nct, 1, &val));
else if constexpr(ischar)
err.Reset(nc_put_att_text(ncid, varid, name.Buf(), strlen(val) + 1, val));
else
err.Reset(nc_put_att_text(ncid, varid, name.Buf(), val.Len() + 1, val.Buf()));
return err.IsErr() ? "Can't write attribute " + name + " to the variable " + vname + ": " + ErrMessage() : "";
}
MString AddAtt(const MString& vname, const MString& name, const char* val)
{
if(err.IsErr()) return "Can't write attribute " + name + " to the variable " + vname + " due to previous errors";
int varid;
err.Reset(nc_inq_varid(ncid, vname.Buf(), &varid));
if(err.IsErr()) return "Can't find variable " + vname + ": " + ErrMessage();
err.Reset(nc_put_att_text(ncid, varid, name.Buf(), strlen(val) + 1, val));
return err.IsErr() ? "Can't write attribute " + name + " to the variable " + vname + ": " + ErrMessage() : "";
}
template<class... T> void AddVar(const MString& vname, nc_type type, const T&... dnames) { AddVar(vname, type, std::vector<MString>({dnames...})); }
void EndDef() const { nc_enddef(ncid); }
void SetComp(const MString& vname, int comp)
{
if(err.IsErr()) return;
int varid;
err.Reset(nc_inq_varid(ncid, vname.Buf(), &varid));
if(err.IsErr()) return;
err.Reset(nc_def_var_deflate(ncid, varid, 1, 1, comp));
}
template<class T>
requires requires(int nc, int vid, const T* d) {
{ NCTypeD<T, void>::put_var(nc, vid, d) } -> std::same_as<int>;
}
void WriteVar(const MString& vname, const T* data)
{
if(err.IsErr()) return;
int varid;
err.Reset(nc_inq_varid(ncid, vname.Buf(), &varid));
if(err.IsErr()) return;
err.Reset(NCTypeD<T, void>::put_var(ncid, varid, data));
}
template<class T>
requires requires(int nc, int vid, const size_t* start, const size_t* count, const T* d) {
{ NCTypeD<T, void>::put_vara(nc, vid, start, count, d) } -> std::same_as<int>;
}
void WriteVar(const MString& vname, size_t ind, const T* data)
{
if(err.IsErr()) return;
int varid;
err.Reset(nc_inq_varid(ncid, vname.Buf(), &varid));
if(err.IsErr()) return;
int ndim;
err.Reset(nc_inq_var(ncid, varid, nullptr, nullptr, &ndim, nullptr, nullptr));
if(err.IsErr()) return;
std::vector<int> dimids(ndim);
err.Reset(nc_inq_var(ncid, varid, nullptr, nullptr, nullptr, dimids.data(), nullptr));
if(err.IsErr()) return;
std::vector<size_t> start(ndim), count(ndim);
start[0] = ind;
count[0] = 1;
for(size_t i = 1; i < dimids.size(); i++)
{
start[i] = 0;
err.Reset(nc_inq_dim(ncid, dimids[i], nullptr, &count[i]));
if(err.IsErr()) return;
}
err.Reset(NCTypeD<T, void>::put_vara(ncid, varid, start.data(), count.data(), data));
}
static constexpr auto fill = std::numeric_limits<float>::max();
private:
// Members
int ncid;
Error err = NC_NOERR;
bool opened = false;
void AddVar(const MString& vname, nc_type type, std::vector<MString>&& dnames)
Type type = UNKNOWN;
union
{
if(err.IsErr()) return;
std::vector<int> dimids(dnames.size());
int varid;
for(size_t i = 0; i < dnames.size(); i++)
struct
{
err.Reset(nc_inq_dimid(ncid, dnames[i].Buf(), &dimids[i]));
if(err.IsErr()) return;
}
err.Reset(nc_def_var(ncid, vname.Buf(), type, dimids.size(), dimids.data(), &varid));
}
};
class NCFileW: public NCFileWBase
{
enum Type
{
UNKNOWN,
PSET,
GPSET,
GRID,
GGRID,
RGRID,
GRGRID
int xdimid, ydimid;
};
static constexpr auto fill = std::numeric_limits<float>::max();
Type type = UNKNOWN;
int dimid[2];
};
int xid, yid;
int compress;
bool tdep = false;
std::vector<struct Var> vars;
template<class D> static constexpr Type DetType()
{
if constexpr(ReadIs2DGeoRectArray<D>) return GRGRID;
if constexpr(ReadIs2DGeoArray<D>) return GGRID;
if constexpr(ReadIs1DGeoArray<D>) return GPSET;
if constexpr(ReadIs2DXYRectArray<D>) return RGRID;
if constexpr(ReadIs2DXYArray<D>) return GRID;
if constexpr(ReadIs1DArray<D>) return PSET;
if constexpr(ReadIs2DGeoRectArray<D>) return G1V2;
if constexpr(ReadIs2DGeoArray<D>) return G2V2;
if constexpr(ReadIs1DGeoArray<D>) return G1V1;
return UNKNOWN;
};
template<class D> static constexpr bool Is1DType() { return Is1DType(DetType<D>()); }
static constexpr bool IsGeoType(Type t) { return t == GPSET || t == GGRID || t == GRGRID; }
static constexpr bool Is1DType(Type t) { return t == PSET || t == GPSET; }
static constexpr bool Is1DType(Type t) { return t == G1V1; }
MString CreateFile(Type stype, const MString& name, int compression, size_t nx, size_t ny);
MString CreateFile(Type stype, const MString& name, const MString& history, int compression, size_t nx, size_t ny);
public:
static constexpr auto Fill() { return fill; }
template<class D> MString Create(const D& data, const MString& name, int compression)
~NCFileW() { Close(); }
template<class D> MString Create(const D& data, const MString& name, const MString& history, int compression)
{
if(type != UNKNOWN) return "File already created";
if constexpr(Is1DType<D>())
return CreateFile(DetType<D>(), name, compression, data.N(), 0);
return CreateFile(DetType<D>(), name, history, compression, data.N(), 0);
else
return CreateFile(DetType<D>(), name, compression, data.Nx(), data.Ny());
return CreateFile(DetType<D>(), name, history, compression, data.Nx(), data.Ny());
}
size_t VarId(const MString& name) const
{
for(size_t i = 0; i < vars.size(); i++)
if(vars[i].name == name) return i + 1;
return 0;
}
bool HaveVar(const MString& name) const { return VarId(name) != 0; }
void EndDef() const
{
if(type != UNKNOWN) nc_enddef(ncid);
}
void Close()
{
NCFileWBase::Close();
if(type != UNKNOWN) nc_close(ncid);
type = UNKNOWN;
}
MString AddTimeData(const TimeData& tdata, bool tisindex);
MString AddVariable(const MString& name, const MString& stname, const MString& lname, const MString& units, const MString& comment);
template<class D, class Op>
requires(std::is_invocable_v<Op, size_t> || std::is_invocable_v<Op, size_t, size_t>)
MString WriteVariable(const D& data, const MString& name, Op op, size_t tind)
template<class D, class Op> MString WriteVariable(const D& data, size_t varid, Op op) const
{
static constexpr auto dtype = DetType<D>();
if(type == UNKNOWN) return "File not open";
if(type != dtype) return "Incompatible data type";
if(varid == 0) return "Incorrect variable";
if constexpr(dtype == UNKNOWN) return "Unknown data type";
size_t v = varid - 1;
EndDef();
int ret;
if constexpr(Is1DType(dtype))
{
const size_t c = data.N();
auto buf = std::make_unique<float[]>(c);
const size_t i = 0, c = data.N();
float buf[c];
for(size_t ix = 0; ix < c; ix++) buf[ix] = data.IsFill(ix) ? fill : op(ix);
if(tdep)
WriteVar(name, tind, buf.get());
else
WriteVar(name, buf.get());
ret = nc_put_vara_float(ncid, vars[v].id, &i, &c, buf);
if(ret != NC_NOERR) return "Can't write " + vars[v].name + " variable in the netcdf file";
}
else
{
const size_t c[2] = {data.Ny(), data.Nx()};
auto buf = std::make_unique<float[]>(c[0] * c[1]);
for(size_t iy = 0; iy < c[0]; iy++)
for(size_t ix = 0; ix < c[1]; ix++) buf[iy * c[1] + ix] = data.IsFill(ix, iy) ? fill : op(ix, iy);
if(tdep)
WriteVar(name, tind, buf.get());
else
WriteVar(name, buf.get());
}
const size_t i[2] = {0, 0};
const size_t c[2] = {data.Nx(), data.Ny()};
float buf[c[0] * c[1]];
if(!*this) return "Can't write variable " + name + ": " + ErrMessage();
for(size_t ix = 0; ix < c[0]; ix++)
for(size_t iy = 0; iy < c[1]; iy++) buf[ix * c[1] + iy] = data.IsFill(ix, iy) ? fill : op(ix, iy);
ret = nc_put_vara_float(ncid, vars[v].id, i, c, buf);
if(ret != NC_NOERR) return "Can't write " + vars[v].name + " variable in the netcdf file";
}
return "";
}
template<class D> MString WriteVariable(const D& data, const MString& name, size_t tind)
template<class D, class Op> MString WriteVariable(const D& data, const MString& name, Op op) const { return WriteVariable(data, VarId(name), op); }
template<class D> MString WriteVariable(const D& data, size_t varid) const
{
if constexpr(Is1DType(DetType<D>()))
return WriteVariable(data, name, [&data = std::as_const(data)](size_t i) { return data(i); }, tind);
return WriteVariable(data, varid, [&data = std::as_const(data)](size_t i) { return data(i); });
else
return WriteVariable(data, name, [&data = std::as_const(data)](size_t i, size_t j) { return data(i, j); }, tind);
return WriteVariable(data, varid, [&data = std::as_const(data)](size_t i, size_t j) { return data(i, j); });
}
template<class D, class Op>
requires(std::is_invocable_v<Op, size_t> || std::is_invocable_v<Op, size_t, size_t>)
MString WriteVariable(const D& data, const MString& name, Op op)
{
return WriteVariable(data, name, op, 0);
}
template<class D> MString WriteVariable(const D& data, const MString& name) { return WriteVariable(data, name, 0); }
template<class D> MString WriteVariable(const D& data, const MString& name) const { return WriteVariable(data, VarId(name)); }
template<class D> MString WriteGrid(const D& data)
template<class D> MString WriteGrid(const D& data) const
{
static constexpr auto dtype = DetType<D>();
if(type == UNKNOWN) return "File not open";
@ -466,87 +146,56 @@ class NCFileW: public NCFileWBase
EndDef();
if constexpr(dtype == UNKNOWN)
return "Unknown data type";
else if constexpr(dtype == PSET)
int ret;
if constexpr(dtype == G1V1)
{
const size_t c = data.N();
const size_t i = 0, c = data.N();
float bufx[c];
float bufy[c];
for(size_t ix = 0; ix < c; ix++)
{
bufx[ix] = data.X(ix);
bufy[ix] = data.Y(ix);
}
WriteVar("x", bufx);
WriteVar("y", bufy);
}
else if constexpr(dtype == GPSET)
{
const size_t c = data.N();
auto bufx = std::make_unique<float[]>(c);
auto bufy = std::make_unique<float[]>(c);
for(size_t ix = 0; ix < c; ix++)
{
bufx[ix] = data.Lon(ix);
bufy[ix] = data.Lat(ix);
}
WriteVar("longitude", bufx.get());
WriteVar("latitude", bufy.get());
}
else if constexpr(dtype == RGRID)
{
const size_t cx = data.Nx(), cy = data.Ny();
auto bufx = std::make_unique<float[]>(cx);
auto bufy = std::make_unique<float[]>(cy);
for(size_t ix = 0; ix < cx; ix++) bufx[ix] = data.Ix2X(ix);
for(size_t iy = 0; iy < cy; iy++) bufy[iy] = data.Iy2Y(iy);
WriteVar("x", bufx.get());
WriteVar("y", bufy.get());
ret = nc_put_vara_float(ncid, xid, &i, &c, bufx);
if(ret != NC_NOERR) return "Can't write longitude variable in the netcdf file";
ret = nc_put_vara_float(ncid, yid, &i, &c, bufy);
if(ret != NC_NOERR) return "Can't write latitude variable in the netcdf file";
}
else if constexpr(dtype == GRGRID)
else if constexpr(dtype == G1V2)
{
const size_t cx = data.Nx(), cy = data.Ny();
auto bufx = std::make_unique<float[]>(cx);
auto bufy = std::make_unique<float[]>(cy);
const size_t i = 0, cx = data.Nx(), cy = data.Ny();
float bufx[cx];
float bufy[cy];
for(size_t ix = 0; ix < cx; ix++) bufx[ix] = data.Ix2Lon(ix);
for(size_t iy = 0; iy < cy; iy++) bufy[iy] = data.Iy2Lat(iy);
WriteVar("longitude", bufx.get());
WriteVar("latitude", bufy.get());
}
else if constexpr(dtype == GRID)
{
const size_t c[2] = {data.Ny(), data.Nx()};
auto bufx = std::make_unique<float[]>(c[0] * c[1]);
auto bufy = std::make_unique<float[]>(c[0] * c[1]);
for(size_t iy = 0; iy < c[0]; iy++)
for(size_t ix = 0; ix < c[1]; ix++)
{
bufx[iy * c[1] + ix] = data.X(ix, iy);
bufy[iy * c[1] + ix] = data.Y(ix, iy);
}
WriteVar("x", bufx.get());
WriteVar("y", bufy.get());
ret = nc_put_vara_float(ncid, xid, &i, &cx, bufx);
if(ret != NC_NOERR) return "Can't write longitude variable in the netcdf file";
ret = nc_put_vara_float(ncid, yid, &i, &cy, bufy);
if(ret != NC_NOERR) return "Can't write latitude variable in the netcdf file";
}
else if constexpr(dtype == GGRID)
else if constexpr(dtype == G2V2)
{
const size_t c[2] = {data.Ny(), data.Nx()};
auto bufx = std::make_unique<float[]>(c[0] * c[1]);
auto bufy = std::make_unique<float[]>(c[0] * c[1]);
for(size_t iy = 0; iy < c[0]; iy++)
for(size_t ix = 0; ix < c[1]; ix++)
const size_t i[2] = {0, 0};
const size_t c[2] = {data.Nx(), data.Ny()};
float bufx[c[0] * c[1]];
float bufy[c[0] * c[1]];
for(size_t ix = 0; ix < c[0]; ix++)
for(size_t iy = 0; iy < c[1]; iy++)
{
bufx[iy * c[1] + ix] = data.Lon(ix, iy);
bufy[iy * c[1] + ix] = data.Lat(ix, iy);
bufx[ix * c[1] + iy] = data.Lon(ix, iy);
bufy[ix * c[1] + iy] = data.Lat(ix, iy);
}
WriteVar("longitude", bufx.get());
WriteVar("latitude", bufy.get());
ret = nc_put_vara_float(ncid, xid, i, c, bufx);
if(ret != NC_NOERR) return "Can't write longitude variable in the netcdf file";
ret = nc_put_vara_float(ncid, yid, i, c, bufy);
if(ret != NC_NOERR) return "Can't write latitude variable in the netcdf file";
}
else
return "Unknown data type";
if(!*this) return MString("Can't write grid: ") + ErrMessage();
return "";
}
};

207
include/ncfuncs.h

@ -1,9 +1,6 @@
#pragma once
#include "DataAdapters/ncfilealt.h"
#include "basedata.h"
#include "mdatetime.h"
#include "nczarr.h"
#include <map>
#include <set>
#include <tuple>
@ -15,10 +12,6 @@ class NCFuncs
{
public:
struct CoordNames
{
MString lonname, latname, depthname, timename;
};
struct DimNames
{
MString lonname, latname, depthname, timename;
size_t nx, ny, nz, nt;
@ -30,203 +23,19 @@ class NCFuncs
static std::tuple<MDateTime, time_t, bool> Refdate(const MString& refdate);
static void GetVars(const NCFileA& nc, std::set<MString>& vars);
static CoordNames GetCNames(const NCFileA& nc);
static DimNames GetDNames(const NCFileA& nc);
static CoordNames GetDNames(const NCFileA& nc);
static bool HaveVar(const NCFileA& nc, const MString& vname);
static void GetVars(const NCZarr& nc, std::set<MString>& vars);
static CoordNames GetCNames(const NCZarr& nc);
static DimNames GetDNames(const NCZarr& nc);
static bool HaveVar(const NCZarr& nc, const MString& vname);
template<class HV> static VarPresence CheckVar(const MString& vname, HV hv)
template<class HV> static bool CheckVar(const MString& vname, HV hv)
{
if(!hv(vname))
{
auto varexist = VarPresence::NONE;
if(vname == "temp" && hv("ptemp") && hv("sal")) varexist = VarPresence::DERIVED;
if(vname == "ptemp" && hv("temp") && hv("sal")) varexist = VarPresence::DERIVED;
if(vname == "pdens" && (hv("ptemp") || hv("temp")) && hv("sal")) varexist = VarPresence::DERIVED;
if((vname == "U" || vname == "U2") && hv("u") && hv("v")) varexist = VarPresence::DERIVED;
if((vname == "ugeo" || vname == "vgeo") && hv("ssh")) varexist = VarPresence::DERIVED;
return varexist;
}
return VarPresence::INTERNAL;
}
template<class D> static bool TransformationRead(const D* data, const MString& vname, std::map<MString, typename D::Data>& cache, const BaseParameters* ip, size_t i)
{
if constexpr(requires(const D* d, const BaseParameters* p) {
{ d->Depth(p) } -> std::convertible_to<real>;
})
{
real depth = data->Depth(ip);
// ptemp from temp and sal
if(vname == "ptemp")
{
if(!(data->Read("temp", cache, ip, i) && data->Read("sal", cache, ip, i))) return false;
cache[vname] = cache.at("temp").CopyGrid();
auto& ptemp = cache.at(vname);
const auto& temp = cache.at("temp");
const auto& sal = cache.at("sal");
ptemp.SetUnit("degrees_C");
for(size_t ind = 0; ind < ptemp.N(); ind++)
{
if(temp.IsFill(ind) || sal.IsFill(ind))
ptemp.V(ind) = ptemp.Fillval();
else
ptemp.V(ind) = Temp2PTemp(temp.V(ind), sal.V(ind), depth, ptemp.Lon(ind), ptemp.Lat(ind));
}
return true;
}
// temp from ptemp and sal
if(vname == "temp")
{
if(!(data->Read("ptemp", cache, ip, i) && data->Read("sal", cache, ip, i))) return false;
cache[vname] = cache.at("ptemp").CopyGrid();
auto& temp = cache.at(vname);
const auto& ptemp = cache.at("ptemp");
const auto& sal = cache.at("sal");
temp.SetUnit("degrees_C");
for(size_t ind = 0; ind < temp.N(); ind++)
{
if(ptemp.IsFill(ind) || sal.IsFill(ind))
temp.V(ind) = temp.Fillval();
else
temp.V(ind) = PTemp2Temp(ptemp.V(ind), sal.V(ind), depth, temp.Lon(ind), temp.Lat(ind));
}
return true;
}
// pdens from temp and sal
if(vname == "pdens")
{
bool tempispot = data->CheckVar("ptemp") == VarPresence::INTERNAL;
if(!(data->Read(tempispot ? "ptemp" : "temp", cache, ip, i) && data->Read("sal", cache, ip, i))) return false;
cache[vname] = cache.at("sal").CopyGrid();
auto& pdens = cache.at(vname);
const auto& temp = cache.at(tempispot ? "ptemp" : "temp");
const auto& sal = cache.at("sal");
pdens.SetUnit("kg m-3");
for(size_t ind = 0; ind < pdens.N(); ind++)
{
if(temp.IsFill(ind) || sal.IsFill(ind))
pdens.V(ind) = pdens.Fillval();
else
pdens.V(ind) =
tempispot ? PTemp2PDens(temp.V(ind), sal.V(ind), depth, pdens.Lon(ind), pdens.Lat(ind)) : Temp2PDens(temp.V(ind), sal.V(ind), depth, pdens.Lon(ind), pdens.Lat(ind));
bool varexist = false;
if(vname == "temp" && hv("ptemp") && hv("sal")) varexist = true;
if(vname == "ptemp" && hv("temp") && hv("sal")) varexist = true;
if(vname == "pdens" && (hv("ptemp") || hv("temp")) && hv("sal")) varexist = true;
if((vname == "U" || vname == "U2") && hv("u") && hv("v")) varexist = true;
if(!varexist) return false;
}
return true;
}
}
// U and U2 from u and v
if(vname == "U" || vname == "U2")
{
bool square = vname == "U2";
if(!(data->Read("u", cache, ip, i) && data->Read("v", cache, ip, i))) return false;
cache[vname] = cache.at("u").CopyGrid();
auto& U = cache.at(vname);
const auto& u = cache.at("u");
const auto& v = cache.at("v");
if(u.Unit().Exist()) U.SetUnit(square ? ("(" + u.Unit() + ")2") : u.Unit());
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 true;
}
// ugeo
if(vname == "ugeo")
{
if(!data->Read("ssh", cache, ip, i)) return false;
const auto& ssh = cache.at("ssh");
const real mul = (ssh.Unit() == "cm") ? 1.0 : ((ssh.Unit() == "m") ? 100.0 : -1.0);
if(mul < 0.0) return false; // Unknown units
cache[vname] = cache.at("ssh").CopyGrid();
auto& ugeo = cache.at(vname);
ugeo.SetUnit("cm/s");
for(size_t iy = 0; iy < ssh.Ny(); iy++)
{
const real phi = michlib::M_PI * ssh.Iy2Lat(iy) / 180.0;
const real sphi = michlib::Sin(phi);
const real s2phi = michlib::Sin(2.0 * phi);
const real g = 978.0318 * (1.0 + 0.005302 * sphi * sphi - 0.000006 * s2phi * s2phi); // g in cm/s
const real f = 2.0 * 7.29211 * sphi; // Coriolis parameter multiplied by 100'000
const real db = (iy == 0) ? 0.0 : (michlib::M_PI * 6371.0 * (ssh.Iy2Lat(iy) - ssh.Iy2Lat(iy - 1)) / 180.0); // Distance in km, compensated by multiplier in Coriolis parameter
const real du =
(iy == ssh.Ny() - 1) ? 0.0 : (michlib::M_PI * 6371.0 * (ssh.Iy2Lat(iy + 1) - ssh.Iy2Lat(iy)) / 180.0); // Distance in km, compensated by multiplier in Coriolis parameter
for(size_t ix = 0; ix < ssh.Nx(); ix++)
{
const bool bok = iy != 0 && !ssh.IsFill(ix, iy - 1) && !ssh.IsFill(ix, iy);
const bool uok = iy != ssh.Ny() - 1 && !ssh.IsFill(ix, iy + 1) && !ssh.IsFill(ix, iy);
if(!(bok || uok))
ugeo(ix, iy) = ugeo.Fillval();
else if(!bok)
ugeo(ix, iy) = -g * mul * (ssh(ix, iy + 1) - ssh(ix, iy)) / (f * du);
else if(!uok)
ugeo(ix, iy) = -g * mul * (ssh(ix, iy) - ssh(ix, iy - 1)) / (f * db);
else
{
const real bder = -g * mul * (ssh(ix, iy) - ssh(ix, iy - 1)) / (f * db);
const real uder = -g * mul * (ssh(ix, iy + 1) - ssh(ix, iy)) / (f * du);
ugeo(ix, iy) = 0.5 * (bder + uder);
}
}
}
return true;
}
// vgeo
if(vname == "vgeo")
{
if(!data->Read("ssh", cache, ip, i)) return false;
const auto& ssh = cache.at("ssh");
const real mul = (ssh.Unit() == "cm") ? 1.0 : ((ssh.Unit() == "m") ? 100.0 : -1.0);
if(mul < 0.0) return false; // Unknown units
cache[vname] = cache.at("ssh").CopyGrid();
auto& vgeo = cache.at(vname);
vgeo.SetUnit("cm/s");
for(size_t iy = 0; iy < ssh.Ny(); iy++)
{
const real phi = michlib::M_PI * ssh.Iy2Lat(iy) / 180.0;
const real sphi = michlib::Sin(phi);
const real cphi = michlib::Cos(phi);
const real s2phi = michlib::Sin(2.0 * phi);
const real g = 978.0318 * (1.0 + 0.005302 * sphi * sphi - 0.000006 * s2phi * s2phi); // g in cm/s
const real f = 2.0 * 7.29211 * sphi; // Coriolis parameter multiplied by 100'000
for(size_t ix = 0; ix < ssh.Nx(); ix++)
{
const real dl =
(ix == 0) ? 0.0 : (michlib::M_PI * 6371.0 * (ssh.Ix2Lon(ix) - ssh.Ix2Lon(ix - 1)) / 180.0) * cphi; // Distance in km, compensated by multiplier in Coriolis parameter
const real dr = (ix == ssh.Nx() - 1)
? 0.0
: (michlib::M_PI * 6371.0 * (ssh.Ix2Lon(ix + 1) - ssh.Ix2Lon(ix)) / 180.0) * cphi; // Distance in km, compensated by multiplier in Coriolis parameter
const bool lok = ix != 0 && !ssh.IsFill(ix - 1, iy) && !ssh.IsFill(ix, iy);
const bool rok = ix != ssh.Nx() - 1 && !ssh.IsFill(ix + 1, iy) && !ssh.IsFill(ix, iy);
if(!(lok || rok))
vgeo(ix, iy) = vgeo.Fillval();
else if(!lok)
vgeo(ix, iy) = g * mul * (ssh(ix + 1, iy) - ssh(ix, iy)) / (f * dr);
else if(!rok)
vgeo(ix, iy) = g * mul * (ssh(ix, iy) - ssh(ix - 1, iy)) / (f * dl);
else
{
const real lder = g * mul * (ssh(ix, iy) - ssh(ix - 1, iy)) / (f * dl);
const real rder = g * mul * (ssh(ix + 1, iy) - ssh(ix, iy)) / (f * dr);
vgeo(ix, iy) = 0.5 * (lder + rder);
}
}
}
return true;
}
return false;
}
};

87
include/ncsimple.h

@ -1,87 +0,0 @@
#pragma once
#include "nczarrcommon.h"
#include <netcdf.h>
#include <variant>
class NCSimpleTypes: public NcZarrTypes
{
protected:
template<class VType> class ReadedData
{
using Vec = std::vector<size_t>;
private:
std::unique_ptr<VType[]> data;
public:
ReadedData() = default;
ReadedData(std::unique_ptr<VType[]>&& d): data(std::move(d)) {}
VType operator()(size_t lini) const { return data[lini]; }
};
};
class NCSimpleFunctions: public NCSimpleTypes
{
int ncid;
RetVal<std::vector<Attribute>> ReadAtts(int vid) const;
protected:
NCSimpleFunctions(): ncid(0) {}
template<class VType> RetVal<ReadedData<VType>> Read(const MString& var, const size_t* start, const size_t* count) const
{
static const MString pref = "NCSimpleFunctions::Read";
size_t ind = FindInd(var, vars);
const size_t N = vars[ind].NDim();
std::unique_ptr<VType[]> cdata;
size_t dsize = 1;
for(size_t i = 0; i < N; i++) dsize *= count[i];
cdata.reset(new VType[dsize]);
int vid;
int res = nc_inq_varid(ncid, var.Buf(), &vid);
if(res != NC_NOERR) return Error(pref, MString("nc_inq_varid error: ") + nc_strerror(res));
if constexpr(std::is_same_v<VType, float>)
res = nc_get_vara_float(ncid, vid, start, count, cdata.get());
else if constexpr(std::is_same_v<VType, double>)
res = nc_get_vara_double(ncid, vid, start, count, cdata.get());
else if constexpr(std::is_same_v<VType, int>)
res = nc_get_vara_int(ncid, vid, start, count, cdata.get());
else if constexpr(std::is_same_v<VType, long>)
res = nc_get_vara_long(ncid, vid, start, count, cdata.get());
else if constexpr(std::is_same_v<VType, long long>)
res = nc_get_vara_longlong(ncid, vid, start, count, cdata.get());
else if constexpr(std::is_same_v<VType, short>)
res = nc_get_vara_short(ncid, vid, start, count, cdata.get());
else if constexpr(std::is_same_v<VType, signed char>)
res = nc_get_vara_schar(ncid, vid, start, count, cdata.get());
else if constexpr(std::is_same_v<VType, unsigned int>)
res = nc_get_vara_uint(ncid, vid, start, count, cdata.get());
else if constexpr(std::is_same_v<VType, unsigned long long>)
res = nc_get_vara_ulonglong(ncid, vid, start, count, cdata.get());
else if constexpr(std::is_same_v<VType, unsigned short>)
res = nc_get_vara_ushort(ncid, vid, start, count, cdata.get());
else if constexpr(std::is_same_v<VType, unsigned char>)
res = nc_get_vara_ubyte(ncid, vid, start, count, cdata.get());
else
return Error(pref, "Unsupported variable type");
if(res != NC_NOERR) return Error(pref, MString("nc_get_vara error: ") + nc_strerror(res));
return ReadedData<VType>(std::move(cdata));
}
public:
~NCSimpleFunctions() { nc_close(ncid); }
Error Open(const MString& filename);
};
using NCSimple = NcZarrRead<NCSimpleFunctions>;

166
include/nczarr.h

@ -1,166 +0,0 @@
#pragma once
#include "nczarrmulti.h"
#include <variant>
using NCZarrBase = std::variant<Zarr, NCSimple, ZarrMulti, NCMulti>;
#define DEFFUNC(NAME) \
auto NAME() const \
{ \
return V([](const auto& arg) { return arg.NAME(); }); \
}
#define DEFFUNC1(NAME) \
auto NAME(const MString& v) const \
{ \
return V([&v = std::as_const(v)](const auto& arg) { return arg.NAME(v); }); \
}
#define DEFFUNC2(NAME) \
auto NAME(const MString& v1, const MString& v2) const \
{ \
return V([&v1 = std::as_const(v1), &v2 = std::as_const(v2)](const auto& arg) { return arg.NAME(v1, v2); }); \
}
class NCZarr: private NCZarrBase, private DimReqDef
{
template<class Visitor> auto V(Visitor&& visitor) const { return std::visit(std::forward<Visitor>(visitor), *static_cast<const NCZarrBase*>(this)); }
public:
explicit operator bool() const
{
return V([](const auto& arg) { return static_cast<bool>(arg); });
}
DEFFUNC1(NDim)
DEFFUNC(NAtt)
DEFFUNC1(NAtt)
DEFFUNC(AttNames)
DEFFUNC1(AttNames)
DEFFUNC(VarNames)
DEFFUNC1(VarT)
DEFFUNC1(VarFill)
DEFFUNC1(DimNames)
DEFFUNC2(DimSize)
DEFFUNC2(AttT)
DEFFUNC2(AttInt)
DEFFUNC2(AttUInt)
DEFFUNC2(AttReal)
DEFFUNC2(AttString)
DEFFUNC2(AttBool)
DEFFUNC1(AttT)
DEFFUNC1(AttInt)
DEFFUNC1(AttUInt)
DEFFUNC1(AttReal)
DEFFUNC1(AttString)
DEFFUNC1(AttBool)
DEFFUNC2(HasDim)
DEFFUNC1(HasVar)
DEFFUNC1(HasAtt)
DEFFUNC2(HasAtt)
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, const char* request) const
{
return V([&vname = std::as_const(vname), &data = data, &transform = transform, request = request](const auto& arg) { return arg.Read(vname, data, transform, request); });
}
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, DimReq&& req1) const
{
return V([&vname = std::as_const(vname), &data = data, &transform = transform, &req1 = req1](const auto& arg) { return arg.Read(vname, data, transform, std::move(req1)); });
}
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, DimReq&& req1, DimReq&& req2) const
{
return V([&vname = std::as_const(vname), &data = data, &transform = transform, &req1 = req1, &req2 = req2](const auto& arg)
{ return arg.Read(vname, data, transform, std::move(req1), std::move(req2)); });
}
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, DimReq&& req1, DimReq&& req2, DimReq&& req3) const
{
return V([&vname = std::as_const(vname), &data = data, &transform = transform, &req1 = req1, &req2 = req2, &req3 = req3](const auto& arg)
{ return arg.Read(vname, data, transform, std::move(req1), std::move(req2), std::move(req3)); });
}
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, DimReq&& req1, DimReq&& req2, DimReq&& req3, DimReq&& req4) const
{
return V([&vname = std::as_const(vname), &data = data, &transform = transform, &req1 = req1, &req2 = req2, &req3 = req3, &req4 = req4](const auto& arg)
{ return arg.Read(vname, data, transform, std::move(req1), std::move(req2), std::move(req3), std::move(req4)); });
}
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform) const
{
return V([&vname = std::as_const(vname), &data = data, &transform = transform](const auto& arg) { return arg.Read(vname, data, transform); });
}
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, const std::vector<DimReqDef::DimReq>& reqs) const
{
return V([&vname = std::as_const(vname), &data = data, &transform = transform, &reqs = std::as_const(reqs)](const auto& arg) { return arg.Read(vname, data, transform, reqs); });
}
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, const MString& request) const
{
return V([&vname = std::as_const(vname), &data = data, &transform = transform, &request = std::as_const(request)](const auto& arg)
{ return arg.Read(vname, data, transform, request); });
}
template<class Type> Error Read(const MString& vname, std::vector<Type>& out) const
{
return V([&vname = std::as_const(vname), &out = out](const auto& arg) { return arg.Read(vname, out); });
}
Error OpenNC(const MString& filename)
{
auto pv = static_cast<NCZarrBase*>(this);
*pv = NCZarrBase(NCSimple());
auto p = std::get_if<NCSimple>(pv);
if(p == nullptr) return Error("NCZarr::OpenNC", "Impossible error!");
return p->Open(filename);
}
Error OpenZarr(const MString& product, const MString& dataset, bool time = true)
{
auto pv = static_cast<NCZarrBase*>(this);
*pv = NCZarrBase(Zarr());
auto p = std::get_if<Zarr>(pv);
if(p == nullptr) return Error("NCZarr::OpenNC", "Impossible error!");
return p->Open(product, dataset, time);
}
Error OpenMultiNC(const std::vector<MString>& names)
{
if(names.size() == 0) return Error("NCZarr::OpenMultiNC", "no names");
if(names.size() == 1) return OpenNC(names[0]);
auto pv = static_cast<NCZarrBase*>(this);
*pv = NCZarrBase(NCMulti());
auto p = std::get_if<NCMulti>(pv);
if(p == nullptr) return Error("NCZarr::OpenMultiNC", "Impossible error!");
return p->Open(names);
}
Error OpenMultiZarr(const MString& product, const std::vector<MString>& dsets, bool time = true)
{
if(dsets.size() == 0) return Error("NCZarr::OpenMultiZarr", "no datasets");
if(dsets.size() == 1) return OpenZarr(product, dsets[0], time);
auto pv = static_cast<NCZarrBase*>(this);
*pv = NCZarrBase(ZarrMulti());
auto p = std::get_if<ZarrMulti>(pv);
if(p == nullptr) return Error("NCZarr::OpenMultiZarr", "Impossible error!");
return p->Open(product, dsets, time);
}
};
#undef DEFFUNC
#undef DEFFUNC1
#undef DEFFUNC2

826
include/nczarrcommon.h

@ -1,826 +0,0 @@
#pragma once
#include "merrors.h"
#include <utility>
#include <variant>
using michlib::Error;
using michlib::int1;
using michlib::int2;
using michlib::int4;
using michlib::int8;
using michlib::int_cast;
using michlib::MString;
using michlib::RetVal;
using michlib::uint1;
using michlib::uint8;
class NcZarrTypes
{
protected:
using AttVT = std::variant<std::monostate, int8, uint8, double, MString, bool>;
class ArrCounter
{
using VT = std::vector<size_t>;
const VT count;
VT ind;
bool end;
public:
static size_t Index(const VT& i, const VT& c)
{
size_t out = 0;
size_t mul = 1;
for(size_t ii = i.size(); ii != 0; ii--)
{
out += mul * i[ii - 1];
mul *= c[ii - 1];
}
return out;
}
static VT Index(size_t lind, const VT& c)
{
VT out(c.size());
size_t j = lind;
for(auto i = c.size(); i > 0; i--)
{
out[i - 1] = j % c[i - 1];
j = j / c[i - 1];
}
return out;
}
ArrCounter() = delete;
ArrCounter(const VT& cnt): count(cnt), ind(cnt.size(), 0), end(false) {}
size_t operator[](size_t i) const { return ind[i]; }
ArrCounter& operator++()
{
size_t curind = count.size();
while(curind != 0)
{
ind[curind - 1]++;
if(ind[curind - 1] >= count[curind - 1])
{
ind[curind - 1] = 0;
curind--;
}
else
return *this;
}
ind = count;
end = true;
return *this;
}
explicit operator bool() const { return !end; }
size_t Index() const { return Index(ind, count); }
size_t Index(const VT& i) const { return Index(i, count); }
VT Index(size_t lind) const { return Index(lind, count); }
size_t Count(size_t i) const { return count[i]; }
const VT& VIndex() const { return ind; }
VT VIndex(const VT& start) const
{
VT out(ind.size());
for(size_t i = 0; i < ind.size(); i++) out[i] = ind[i] + start[i];
return out;
}
const auto& Count() const { return count; }
size_t N() const
{
size_t out = 1;
for(size_t i = 0; i < count.size(); i++) out *= count[i];
return out;
}
};
public:
enum class AttType
{
UNDEF,
INT,
UINT,
REAL,
STRING,
BOOL
};
enum class VarType
{
UNDEF,
FLOAT,
DOUBLE,
INT1,
INT2,
INT4,
INT8,
UINT1
};
protected:
template<VarType VT, class Dummy = void> struct VarType2Type;
template<class Dummy> struct VarType2Type<VarType::FLOAT, Dummy>
{
using type = float;
};
template<class Dummy> struct VarType2Type<VarType::DOUBLE, Dummy>
{
using type = double;
};
template<class Dummy> struct VarType2Type<VarType::INT1, Dummy>
{
using type = int1;
};
template<class Dummy> struct VarType2Type<VarType::INT2, Dummy>
{
using type = int2;
};
template<class Dummy> struct VarType2Type<VarType::INT4, Dummy>
{
using type = int4;
};
template<class Dummy> struct VarType2Type<VarType::INT8, Dummy>
{
using type = int8;
};
template<class Dummy> struct VarType2Type<VarType::UINT1, Dummy>
{
using type = uint1;
};
template<VarType VT> using Type = VarType2Type<VT>::type;
static constexpr size_t SizeOf(VarType vt)
{
switch(vt)
{
case(VarType::UNDEF): return 0;
case(VarType::FLOAT): return sizeof(Type<VarType::FLOAT>);
case(VarType::DOUBLE): return sizeof(Type<VarType::DOUBLE>);
case(VarType::INT1): return sizeof(Type<VarType::INT1>);
case(VarType::INT2): return sizeof(Type<VarType::INT2>);
case(VarType::INT4): return sizeof(Type<VarType::INT4>);
case(VarType::INT8): return sizeof(Type<VarType::INT8>);
case(VarType::UINT1): return sizeof(Type<VarType::UINT1>);
}
return 0;
}
template<class T> static size_t FindInd(const MString& name, const std::vector<T>& arr)
{
for(size_t i = 0; i < arr.size(); i++)
if(arr[i].Name() == name) return i;
return arr.size();
}
class Attribute: public AttVT
{
MString name;
public:
Attribute(const MString& n, AttVT&& v): AttVT(std::move(v)), name(n) {}
Attribute(const std::string& n, AttVT&& v): AttVT(std::move(v)), name(n.c_str(), n.size()) {}
const MString& Name() const { return name; }
AttType Type() const
{
if(std::holds_alternative<int8>(*this))
return AttType::INT;
else if(std::holds_alternative<uint8>(*this))
return AttType::UINT;
else if(std::holds_alternative<double>(*this))
return AttType::REAL;
else if(std::holds_alternative<MString>(*this))
return AttType::STRING;
else if(std::holds_alternative<bool>(*this))
return AttType::BOOL;
return AttType::UNDEF;
}
int8 I() const
{
if(std::holds_alternative<int8>(*this))
return std::get<int8>(*this);
else if(std::holds_alternative<uint8>(*this))
return int_cast<int8>(std::get<uint8>(*this));
else if(std::holds_alternative<double>(*this))
return static_cast<int8>(std::get<double>(*this));
else if(std::holds_alternative<MString>(*this))
return std::get<MString>(*this).ToInteger<int8>();
else if(std::holds_alternative<bool>(*this))
return std::get<bool>(*this) ? 1 : 0;
return 0;
}
uint8 U() const
{
if(std::holds_alternative<int8>(*this))
return int_cast<uint8>(std::get<int8>(*this));
else if(std::holds_alternative<uint8>(*this))
return std::get<uint8>(*this);
else if(std::holds_alternative<double>(*this))
return static_cast<uint8>(std::get<double>(*this));
else if(std::holds_alternative<MString>(*this))
return std::get<MString>(*this).ToInteger<uint8>();
else if(std::holds_alternative<bool>(*this))
return std::get<bool>(*this) ? 1 : 0;
return 0;
}
double D() const
{
if(std::holds_alternative<int8>(*this))
return std::get<int8>(*this);
else if(std::holds_alternative<uint8>(*this))
return std::get<uint8>(*this);
else if(std::holds_alternative<double>(*this))
return std::get<double>(*this);
else if(std::holds_alternative<MString>(*this))
return michlib_internal::RealType<sizeof(double)>::String2Real(std::get<MString>(*this).Buf());
else if(std::holds_alternative<bool>(*this))
return std::get<bool>(*this) ? 1 : 0;
return 0;
}
MString S() const
{
if(std::holds_alternative<int8>(*this))
return MString().FromInt(std::get<int8>(*this));
else if(std::holds_alternative<uint8>(*this))
return MString().FromUInt(std::get<uint8>(*this));
else if(std::holds_alternative<double>(*this))
return MString().FromReal(std::get<double>(*this));
else if(std::holds_alternative<MString>(*this))
return std::get<MString>(*this);
else if(std::holds_alternative<bool>(*this))
return MString().FromBool(std::get<bool>(*this));
return "";
}
bool B() const
{
if(std::holds_alternative<int8>(*this))
return std::get<int8>(*this) != 0;
else if(std::holds_alternative<uint8>(*this))
return std::get<uint8>(*this) != 0;
else if(std::holds_alternative<double>(*this))
return std::get<double>(*this) != 0.0;
else if(std::holds_alternative<MString>(*this))
return std::get<MString>(*this).ToBool();
else if(std::holds_alternative<bool>(*this))
return std::get<bool>(*this);
return false;
}
};
class Dimension
{
MString name;
size_t size;
public:
Dimension(const MString& str, size_t num): name(str), size(num) {}
const MString& Name() const { return name; }
size_t Size() const { return size; }
};
class Variable
{
public:
using FillType = std::variant<std::monostate, int8, uint8, double>;
private:
MString name;
VarType type = VarType::UNDEF;
std::vector<size_t> dims;
std::vector<Attribute> atts;
FillType fill;
public:
Variable(const MString& name_, VarType type_, std::vector<size_t>&& dims_, std::vector<Attribute>&& atts_, FillType fill_ = 0):
name(name_), type(type_), dims(std::move(dims_)), atts(std::move(atts_)), fill(fill_)
{
}
explicit operator bool() const { return type != VarType::UNDEF; }
const auto& Dims() const { return dims; }
size_t NDim() const { return dims.size(); }
size_t NAtt() const { return atts.size(); }
auto AttNames() const
{
std::vector<MString> out;
std::transform(atts.cbegin(), atts.cend(), std::back_inserter(out), [](const Attribute& a) { return a.Name(); });
return out;
}
AttType AttT(const MString& name) const
{
size_t ind = FindInd(name, atts);
return ind < atts.size() ? atts[ind].Type() : AttType::UNDEF;
}
int8 AttInt(const MString& name) const
{
size_t ind = FindInd(name, atts);
return ind < atts.size() ? atts[ind].I() : 0;
}
uint8 AttUInt(const MString& name) const
{
size_t ind = FindInd(name, atts);
return ind < atts.size() ? atts[ind].U() : 0;
}
double AttReal(const MString& name) const
{
size_t ind = FindInd(name, atts);
return ind < atts.size() ? atts[ind].D() : 0.0;
}
MString AttString(const MString& name) const
{
size_t ind = FindInd(name, atts);
return ind < atts.size() ? atts[ind].S() : MString();
}
bool AttBool(const MString& name) const
{
size_t ind = FindInd(name, atts);
return ind < atts.size() ? atts[ind].B() : false;
}
const MString& Name() const { return name; }
auto Type() const { return type; }
const auto& Fill() const { return fill; }
};
protected:
std::vector<Attribute> gats;
std::vector<Dimension> dims;
std::vector<Variable> vars;
public:
explicit operator bool() const { return !vars.empty(); }
size_t NDim(const MString& var) const
{
size_t ind = FindInd(var, vars);
return ind < vars.size() ? vars[ind].NDim() : 0;
}
size_t NAtt() const { return gats.size(); }
auto AttNames() const
{
std::vector<MString> out;
std::transform(gats.cbegin(), gats.cend(), std::back_inserter(out), [](const Attribute& a) { return a.Name(); });
return out;
}
size_t NAtt(const MString& var) const
{
if(!var.Exist()) return NAtt();
size_t ind = FindInd(var, vars);
return ind < vars.size() ? vars[ind].NAtt() : 0;
}
auto AttNames(const MString& var) const
{
if(!var.Exist()) return AttNames();
size_t ind = FindInd(var, vars);
return ind < vars.size() ? vars[ind].AttNames() : decltype(AttNames())();
}
auto VarNames() const
{
std::vector<MString> out;
std::transform(vars.cbegin(), vars.cend(), std::back_inserter(out), [](const Variable& v) { return v.Name(); });
return out;
}
VarType VarT(const MString& var) const
{
size_t ind = FindInd(var, vars);
return ind < vars.size() ? vars[ind].Type() : VarType::UNDEF;
}
auto VarFill(const MString& var) const
{
size_t ind = FindInd(var, vars);
return ind < vars.size() ? vars[ind].Fill() : Variable::FillType();
}
auto DimNames(const MString& var) const
{
size_t ind = FindInd(var, vars);
std::vector<MString> out;
if(ind >= vars.size()) return out;
auto vdims = vars[ind].Dims();
std::transform(vdims.cbegin(), vdims.cend(), std::back_inserter(out), [&dims = std::as_const(dims)](const size_t& i) { return dims[i].Name(); });
return out;
}
size_t DimSize(const MString& var, const MString& dim) const
{
if(!HasDim(var, dim)) return 0;
size_t ind = FindInd(dim, dims);
return ind < dims.size() ? dims[ind].Size() : 0;
}
AttType AttT(const MString& var, const MString& name) const
{
if(!var.Exist())
{
size_t ind = FindInd(name, gats);
return ind < gats.size() ? gats[ind].Type() : AttType::UNDEF;
}
size_t ind = FindInd(var, vars);
return ind < vars.size() ? vars[ind].AttT(name) : AttType::UNDEF;
}
int8 AttInt(const MString& var, const MString& name) const
{
if(!var.Exist())
{
size_t ind = FindInd(name, gats);
return ind < gats.size() ? gats[ind].I() : 0;
}
size_t ind = FindInd(var, vars);
return ind < vars.size() ? vars[ind].AttInt(name) : 0;
}
uint8 AttUInt(const MString& var, const MString& name) const
{
if(!var.Exist())
{
size_t ind = FindInd(name, gats);
return ind < gats.size() ? gats[ind].U() : 0;
}
size_t ind = FindInd(var, vars);
return ind < vars.size() ? vars[ind].AttUInt(name) : 0;
}
double AttReal(const MString& var, const MString& name) const
{
if(!var.Exist())
{
size_t ind = FindInd(name, gats);
return ind < gats.size() ? gats[ind].D() : 0.0;
}
size_t ind = FindInd(var, vars);
return ind < vars.size() ? vars[ind].AttReal(name) : 0.0;
}
MString AttString(const MString& var, const MString& name) const
{
if(!var.Exist())
{
size_t ind = FindInd(name, gats);
return ind < gats.size() ? gats[ind].S() : MString();
}
size_t ind = FindInd(var, vars);
return ind < vars.size() ? vars[ind].AttString(name) : MString();
}
bool AttBool(const MString& var, const MString& name) const
{
if(!var.Exist())
{
size_t ind = FindInd(name, gats);
return ind < gats.size() ? gats[ind].B() : false;
}
size_t ind = FindInd(var, vars);
return ind < vars.size() ? vars[ind].AttBool(name) : false;
}
auto AttT(const MString& name) const { return AttT("", name); }
auto AttInt(const MString& name) const { return AttInt("", name); }
auto AttUInt(const MString& name) const { return AttUInt("", name); }
auto AttReal(const MString& name) const { return AttReal("", name); }
auto AttString(const MString& name) const { return AttString("", name); }
auto AttBool(const MString& name) const { return AttBool("", name); }
bool HasDim(const MString& var, const MString& name) const
{
size_t vind = FindInd(var, vars);
if(vind >= vars.size()) return false;
for(const auto dind: vars[vind].Dims())
if(dims[dind].Name() == name) return true;
return false;
}
bool HasVar(const MString& name) const { return FindInd(name, vars) < vars.size(); }
bool HasAtt(const MString& vname, const MString& aname) const { return AttT(vname, aname) != AttType::UNDEF; }
bool HasAtt(const MString& aname) const { return AttT(aname) != AttType::UNDEF; }
};
class DimReqDef
{
protected:
struct DimReq
{
static const auto fill = std::numeric_limits<size_t>::max();
MString name;
size_t beg, count;
DimReq(): name(MString()), beg(fill), count(fill) {}
DimReq(const char* n): name(n), beg(fill), count(fill) {}
DimReq(const MString& n): name(n), beg(fill), count(fill) {}
DimReq(MString&& n): name(std::move(n)), beg(fill), count(fill) {}
DimReq(const char* n, size_t s): name(n), beg(s), count(fill) {}
DimReq(const MString& n, size_t s): name(n), beg(s), count(fill) {}
DimReq(MString&& n, size_t s): name(std::move(n)), beg(s), count(fill) {}
DimReq(const char* n, size_t s, size_t c): name(n), beg(s), count(c) {}
DimReq(const MString& n, size_t s, size_t c): name(n), beg(s), count(c) {}
DimReq(MString&& n, size_t s, size_t c): name(std::move(n)), beg(s), count(c) {}
const MString& Name() const { return name; }
};
};
template<class C> class NcZarrRead: public C, public DimReqDef
{
template<class Data> static constexpr size_t Dimensionity()
{
if constexpr(requires(Data& d) { d(0, 0, 0, 0); }) return 4;
if constexpr(requires(Data& d) { d(0, 0, 0); }) return 3;
if constexpr(requires(Data& d) { d(0, 0); }) return 2;
if constexpr(requires(Data& d) { d(0); }) return 1;
return 0;
}
template<class Data, size_t D, class Dummy = void> struct DataTypeExtractorS;
template<class Data, class Dummy> struct DataTypeExtractorS<Data, 1, Dummy>
{
using type = std::decay_t<decltype(std::declval<Data>()(0))>;
};
template<class Data, class Dummy> struct DataTypeExtractorS<Data, 2, Dummy>
{
using type = std::decay_t<decltype(std::declval<Data>()(0, 0))>;
};
template<class Data, class Dummy> struct DataTypeExtractorS<Data, 3, Dummy>
{
using type = std::decay_t<decltype(std::declval<Data>()(0, 0, 0))>;
};
template<class Data, class Dummy> struct DataTypeExtractorS<Data, 4, Dummy>
{
using type = std::decay_t<decltype(std::declval<Data>()(0, 0, 0, 0))>;
};
template<class Data> using DataTypeExtractor = DataTypeExtractorS<Data, Dimensionity<Data>()>::type;
template<class VType, class Data, class Transform>
Error Read(const MString& vname, const std::vector<size_t>& transindex, Data& data, Transform transform, std::vector<DimReq> reqs) const
{
const size_t indim = reqs.size();
constexpr size_t outdim = Dimensionity<Data>();
std::vector<size_t> start;
std::vector<size_t> count;
start.resize(indim);
count.resize(indim);
for(size_t i = 0; i < indim; i++)
{
start[i] = reqs[i].beg;
count[i] = reqs[i].count;
}
using DataType = DataTypeExtractor<Data>;
DataType fillout;
bool havefill = C::VarFill(vname).index() > 0;
VType fillin = std::visit(
[](auto v)
{
if constexpr(std::is_convertible_v<decltype(v), VType>)
return static_cast<VType>(v);
else
return std::numeric_limits<VType>::max();
},
C::VarFill(vname));
if constexpr(requires(Data& d) { // Data have own fillvalue
{ d.Fillval() } -> std::convertible_to<DataType>;
})
fillout = data.Fillval();
else // Data does'nt have own fillvalue, using variable fillvalue
fillout = static_cast<DataType>(fillin);
auto ret = C::template Read<VType>(vname, start.data(), count.data());
if(!ret) return ret;
const auto& rawdata = ret.Value();
std::vector<size_t> mul(indim, 1);
for(size_t i = indim - 1; i > 0; i--) mul[i - 1] = mul[i] * count[i];
size_t inind = 0;
for(typename C::ArrCounter i(count); i; ++i)
{
// TODO: Remove this testing block
size_t cind = 0;
for(size_t j = 0; j < indim; j++) cind += i[j] * mul[j];
if(cind != inind) return {"NcZarrRead::Read", "Internal error"};
if(i.Index() != inind) return {"NcZarrRead::Read", "Internal error"};
if(inind != i.Index(i.Index(inind, count), count)) return {"NcZarrRead::Read", "Internal error"};
DataType out;
const VType& in = rawdata(inind);
if(havefill && in == fillin)
out = fillout;
else
out = transform(in);
if constexpr(outdim == 1)
data(i[transindex[0]]) = out;
else if constexpr(outdim == 2)
data(i[transindex[0]], i[transindex[1]]) = out;
else if constexpr(outdim == 3)
data(i[transindex[0]], i[transindex[1]], i[transindex[2]]) = out;
else if constexpr(outdim == 4)
data(i[transindex[0]], i[transindex[1]], i[transindex[2]], i[transindex[3]]) = out;
inind++;
}
return Error();
}
public:
// Request is string
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, const char* request) const
{
return Read(vname, data, transform, MString(request));
}
// Request by one dimension
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, DimReq&& req1) const
{
return Read(vname, data, transform, std::vector<DimReq>{std::move(req1)});
}
// Request by two dimension
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, DimReq&& req1, DimReq&& req2) const
{
return Read(vname, data, transform, std::vector<DimReq>{std::move(req1), std::move(req2)});
}
// Request by three dimension
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, DimReq&& req1, DimReq&& req2, DimReq&& req3) const
{
return Read(vname, data, transform, std::vector<DimReq>{std::move(req1), std::move(req2), std::move(req3)});
}
// Request by four dimension
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, DimReq&& req1, DimReq&& req2, DimReq&& req3, DimReq&& req4) const
{
return Read(vname, data, transform, std::vector<DimReq>{std::move(req1), std::move(req2), std::move(req3), std::move(req4)});
}
// Request full variable
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform) const
{
static const MString pref = "NcZarrRead::Read";
if(!C::HasVar(vname)) return {pref, "Variable " + vname + " not found"};
std::vector<struct DimReq> pdims;
const auto vdims = C::DimNames(vname);
std::transform(vdims.cbegin(), vdims.cend(), std::back_inserter(pdims),
[this, &vname = std::as_const(vname)](const MString& n) -> struct DimReq { return {n, 0, C::DimSize(vname, n)}; });
return Read(vname, data, transform, pdims);
}
// Base function for all Read's
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, const std::vector<DimReq>& reqs) const
{
static const MString pref = "NcZarrRead::Read";
if(!C::HasVar(vname)) return {pref, "Variable " + vname + " not found"};
std::vector<struct DimReq> pdims;
{
const auto vdims = C::DimNames(vname);
std::transform(vdims.cbegin(), vdims.cend(), std::back_inserter(pdims), [](const MString& n) -> struct DimReq { return {n, 0, 1}; });
}
std::vector<size_t> transindex;
// Parse request
if(reqs.size() == 0) return {pref, "Empty request"};
for(const auto& req: reqs)
{
size_t ind = C::FindInd(req.name, pdims);
if(ind >= pdims.size()) return {pref, "Variable " + vname + " has no dimension " + req.name};
for(size_t i = 0; i < transindex.size(); i++)
if(transindex[i] == ind) return {pref, "Parameters for dimension " + req.name + " already defined"};
transindex.push_back(ind);
size_t dlen = C::DimSize(vname, pdims[ind].name);
if(req.beg == req.fill && req.count == req.fill) // Only name, so, we request full length
{
pdims[ind].beg = 0;
pdims[ind].count = dlen;
}
else if(req.count == req.fill) // Name and first index
{
pdims[ind].beg = req.beg;
pdims[ind].count = 1;
}
else // Name, first index, count
{
pdims[ind].beg = req.beg;
pdims[ind].count = req.count;
}
// Sanity checks
if(pdims[ind].count <= 0) return {pref, "Error parsing request: count must be greter then zero"};
if(pdims[ind].beg >= dlen) return {pref, MString("Error parsing request: start index ") + pdims[ind].beg + " must be lesser then " + pdims[ind].name + " size " + dlen};
if(pdims[ind].beg + pdims[ind].count > dlen)
return {pref, MString("Error parsing request: start index ") + pdims[ind].beg + " with count " + pdims[ind].count + " exceeds " + pdims[ind].name + " size " + dlen};
// Ignore hyperplanes in requests for calculation of data dimensionality
if(pdims[transindex.back()].count == 1) transindex.pop_back();
}
if(transindex.size() != Dimensionity<Data>())
return {pref, MString("Output data dimensions (") + Dimensionity<Data>() + ") not corresponding request dimensions (" + transindex.size() + ")"};
switch(C::VarT(vname))
{
case(C::VarType::UNDEF): return {pref, "No variable with name " + vname + " (impossible)"};
case(C::VarType::FLOAT): return Read<typename C::template Type<C::VarType::FLOAT>>(vname, transindex, data, transform, pdims);
case(C::VarType::DOUBLE): return Read<typename C::template Type<C::VarType::DOUBLE>>(vname, transindex, data, transform, pdims);
case(C::VarType::INT1): return Read<typename C::template Type<C::VarType::INT1>>(vname, transindex, data, transform, pdims);
case(C::VarType::INT2): return Read<typename C::template Type<C::VarType::INT2>>(vname, transindex, data, transform, pdims);
case(C::VarType::INT4): return Read<typename C::template Type<C::VarType::INT4>>(vname, transindex, data, transform, pdims);
case(C::VarType::INT8): return Read<typename C::template Type<C::VarType::INT8>>(vname, transindex, data, transform, pdims);
case(C::VarType::UINT1): return Read<typename C::template Type<C::VarType::INT1>>(vname, transindex, data, transform, pdims);
}
return {pref, "Internal error (impossible)"};
}
// Request by string argument
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, const MString& request) const
{
static const MString pref = "NcZarrRead::Read";
std::vector<struct DimReq> pdims;
// Parse request
const auto dimdesc = request.Split(";, \t");
if(dimdesc.size() == 0) return {pref, "Empty request"};
for(const auto& dd: dimdesc)
{
const auto dimpar = dd.Split(":", true);
if(dimpar.size() == 1) // Only name, so, we request full length
pdims.emplace_back(dimpar[0]);
else if(dimpar.size() == 2) // Name and first index
pdims.emplace_back(dimpar[0], dimpar[1].ToInteger<size_t>());
else if(dimpar.size() == 3) // Name, first index, count
pdims.emplace_back(dimpar[0], dimpar[1].ToInteger<size_t>(), dimpar[2].ToInteger<size_t>());
else
return {pref, "Can't parse expression " + dd};
}
return Read(vname, data, transform, pdims);
}
// Request full one-dimensional variable
template<class Type> Error Read(const MString& vname, std::vector<Type>& out) const
{
const auto& dnames = C::DimNames(vname);
if(dnames.size() > 0) out.resize(C::DimSize(vname, dnames[0]));
auto data = [&vec = out](size_t i) -> Type& { return vec[i]; };
return Read(vname, data, std::identity());
}
};

206
include/nczarrmulti.h

@ -1,206 +0,0 @@
#pragma once
#include "ncsimple.h"
#include "zarr.h"
#include <set>
#define DEFFUNC(func, def) \
auto func(const MString& var) const \
{ \
const auto ind = FindVar(var); \
return ind < sources.size() ? sources[ind].func(var) : (def); \
}
#define DEFFUNCA(func, def) \
auto func(const MString& att) const \
{ \
const auto ind = FindAtt(att); \
return ind < sources.size() ? sources[ind].func(att) : (def); \
}
#define DEFFUNC2(func, def) \
auto func(const MString& var, const MString& name) const \
{ \
const auto ind = FindVar(var); \
return ind < sources.size() ? sources[ind].func(var, name) : (def); \
}
#define DEFFUNCNAMES(func) \
auto func() const \
{ \
std::set<MString> names; \
for(const auto& s: sources) \
{ \
auto snames = s.func(); \
for(const auto& name: snames) names.insert(name); \
} \
std::vector<MString> out; \
for(const auto& name: names) out.push_back(name); \
return out; \
}
template<class T> class NCZarrMultiCommon: private DimReqDef
{
protected:
std::vector<T> sources;
private:
size_t FindVar(const MString& var) const
{
for(size_t i = 0; i < sources.size(); i++)
if(sources[i].HasVar(var)) return i;
return sources.size();
}
size_t FindAtt(const MString& att) const
{
for(size_t i = 0; i < sources.size(); i++)
if(sources[i].HasAtt(att)) return i;
return sources.size();
}
public:
explicit operator bool() const
{
if(sources.empty()) return false;
for(const auto& s: sources)
if(!s) return false;
return true;
}
size_t NDim() const { return DimNames().size(); }
DEFFUNC(NDim, 0)
size_t NAtt() const { return AttNames().size(); }
DEFFUNC(NAtt, 0)
DEFFUNCNAMES(AttNames)
DEFFUNC(AttNames, decltype(AttNames())())
DEFFUNCNAMES(VarNames)
DEFFUNC(VarT, T::VarType::UNDEF)
DEFFUNC(VarFill, decltype(T().VarFill(MString()))())
DEFFUNC(DimNames, decltype(T().DimNames(MString()))())
DEFFUNC2(DimSize, 0)
DEFFUNC2(AttT, T::AttType::UNDEF)
DEFFUNC2(AttInt, 0)
DEFFUNC2(AttUInt, 0)
DEFFUNC2(AttReal, 0.0)
DEFFUNC2(AttString, MString())
DEFFUNC2(AttBool, false)
DEFFUNCA(AttT, T::AttType::UNDEF)
DEFFUNCA(AttInt, 0)
DEFFUNCA(AttUInt, 0)
DEFFUNCA(AttReal, 0.0)
DEFFUNCA(AttString, MString())
DEFFUNCA(AttBool, false)
DEFFUNC2(HasDim, false)
DEFFUNC(HasVar, false)
DEFFUNCA(HasAtt, false)
DEFFUNC2(HasAtt, false)
// Request is string
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, const char* request) const
{
return Read(vname, data, transform, MString(request));
}
// Request by one dimension
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, DimReq&& req1) const
{
return Read(vname, data, transform, std::vector<DimReq>{std::move(req1)});
}
// Request by two dimension
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, DimReq&& req1, DimReq&& req2) const
{
return Read(vname, data, transform, std::vector<DimReq>{std::move(req1), std::move(req2)});
}
// Request by three dimension
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, DimReq&& req1, DimReq&& req2, DimReq&& req3) const
{
return Read(vname, data, transform, std::vector<DimReq>{std::move(req1), std::move(req2), std::move(req3)});
}
// Request by four dimension
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, DimReq&& req1, DimReq&& req2, DimReq&& req3, DimReq&& req4) const
{
return Read(vname, data, transform, std::vector<DimReq>{std::move(req1), std::move(req2), std::move(req3), std::move(req4)});
}
// Request full variable
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform) const
{
auto ind = FindVar(vname);
if(ind < sources.size()) return sources[ind].Read(vname, data, transform);
return Error("NCZarrMultiCommon::Read", "Variable " + vname + " not found");
}
// Base function for all Read's
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, const std::vector<DimReqDef::DimReq>& reqs) const
{
auto ind = FindVar(vname);
if(ind < sources.size()) return sources[ind].Read(vname, data, transform, reqs);
return Error("NCZarrMultiCommon::Read", "Variable " + vname + " not found");
}
// Request by string argument
template<class Data, class Transform> Error Read(const MString& vname, Data& data, Transform transform, const MString& request) const
{
auto ind = FindVar(vname);
if(ind < sources.size()) return sources[ind].Read(vname, data, transform, request);
return Error("NCZarrMultiCommon::Read", "Variable " + vname + " not found");
}
// Request full one-dimensional variable
template<class Type> Error Read(const MString& vname, std::vector<Type>& out) const
{
auto ind = FindVar(vname);
if(ind < sources.size()) return sources[ind].Read(vname, out);
return Error("NCZarrMultiCommon::Read", "Variable " + vname + " not found");
}
};
#undef DEFFUNC
#undef DEFFUNCA
#undef DEFFUNC2
#undef DEFFUNCNAME
class NCMulti: public NCZarrMultiCommon<NCSimple>
{
public:
Error Open(const std::vector<MString>& names)
{
sources.clear();
decltype(sources) newsources;
static const MString pref = "NcMulti::Open";
if(names.size() == 0) return Error(pref, "empty file list");
for(const auto& name: names)
{
newsources.emplace_back();
auto ret = newsources.back().Open(name);
if(!ret) return ret.Add(pref, "Can't open file " + name);
}
sources = std::move(newsources);
return Error();
}
};
class ZarrMulti: public NCZarrMultiCommon<Zarr>
{
public:
Error Open(const MString& product, const std::vector<MString>& dsets, bool time = true)
{
sources.clear();
decltype(sources) newsources;
static const MString pref = "ZarrMulti::Open";
if(dsets.size() == 0) return Error(pref, "empty datasets list");
for(const auto& dset: dsets)
{
newsources.emplace_back();
auto ret = newsources.back().Open(product, dset, time);
if(!ret) return ret.Add(pref, "Can't open dataset " + dset);
}
sources = std::move(newsources);
return Error();
}
};

132
include/simple2ddata.h

@ -1,8 +1,7 @@
#pragma once
#include "basedata.h"
#include "geohelpers.h"
using michlib::M_PI;
using michlib::Floor;
class Simple2DData: public BaseData
{
@ -10,8 +9,6 @@ class Simple2DData: public BaseData
size_t nx = 0, ny = 0;
real xstep = 0.0, ystep = 0.0;
static real D(real lon1, real lat1, real lon2, real lat2) { return michlib::GCD(lon1 * M_PI / 180.0, lat1 * M_PI / 180.0, lon2 * M_PI / 180.0, lat2 * M_PI / 180.0) * 6371.0; }
public:
using BaseData::IsFill;
using BaseData::V;
@ -48,82 +45,21 @@ class Simple2DData: public BaseData
real XStep() const { return xstep; }
real YStep() const { return ystep; }
struct GridPoint GridPos(real x, real y) const
{
struct GridPoint out;
if(!*this) return out;
if(x < x0 || x > x0 + (nx - 1) * xstep || y < y0 || y > y0 + (ny - 1) * ystep) return out;
real rx = x - x0;
real ry = y - y0;
out.ix = static_cast<decltype(out.ix)>(michlib::Floor(rx / xstep));
out.iy = static_cast<decltype(out.ix)>(michlib::Floor(ry / ystep));
out.x = rx - out.ix * xstep;
out.y = ry - out.iy * ystep;
return out;
}
real dVdX(size_t ix, size_t iy) const
{
if(IsFill(ix, iy)) return Fillval();
if(ix == 0 || IsFill(ix - 1, iy))
{
if(IsFill(ix + 1, iy))
return Fillval();
else
return (V(ix + 1, iy) - V(ix, iy)) / D(Lon(ix, iy), Lat(ix, iy), Lon(ix + 1, iy), Lat(ix + 1, iy));
}
if(ix == nx - 1 || IsFill(ix + 1, iy))
{
if(IsFill(ix - 1, iy))
return Fillval();
else
return (V(ix, iy) - V(ix - 1, iy)) / D(Lon(ix - 1, iy), Lat(ix - 1, iy), Lon(ix, iy), Lat(ix, iy));
}
return 0.5 * ((V(ix + 1, iy) - V(ix, iy)) / D(Lon(ix, iy), Lat(ix, iy), Lon(ix + 1, iy), Lat(ix + 1, iy)) +
(V(ix, iy) - V(ix - 1, iy)) / D(Lon(ix - 1, iy), Lat(ix - 1, iy), Lon(ix, iy), Lat(ix, iy)));
}
real dVdY(size_t ix, size_t iy) const
{
if(IsFill(ix, iy)) return Fillval();
if(iy == 0 || IsFill(ix, iy - 1))
{
if(IsFill(ix, iy + 1))
return Fillval();
else
return (V(ix, iy + 1) - V(ix, iy)) / D(Lon(ix, iy), Lat(ix, iy), Lon(ix, iy + 1), Lat(ix, iy + 1));
}
if(iy == ny - 1 || IsFill(ix, iy + 1))
{
if(IsFill(ix, iy - 1))
return Fillval();
else
return (V(ix, iy) - V(ix, iy - 1)) / D(Lon(ix, iy - 1), Lat(ix, iy - 1), Lon(ix, iy), Lat(ix, iy));
}
return 0.5 * ((V(ix, iy + 1) - V(ix, iy)) / D(Lon(ix, iy), Lat(ix, iy), Lon(ix, iy + 1), Lat(ix, iy + 1)) +
(V(ix, iy) - V(ix, iy - 1)) / D(Lon(ix, iy - 1), Lat(ix, iy - 1), Lon(ix, iy), Lat(ix, iy)));
}
real Grad(size_t ix, size_t iy) const
auto GridPoint(real lon, real lat) const
{
real grx = dVdX(ix, iy);
real gry = dVdY(ix, iy);
if(grx == Fillval() || gry == Fillval()) return Fillval();
return michlib::Hypot(grx, gry);
struct GridPointLocation loc;
loc.ix = static_cast<size_t>(Floor((lon - x0) / xstep));
loc.iy = static_cast<size_t>(Floor((lat - y0) / ystep));
loc.x = lon - x0 - loc.ix * xstep;
loc.y = lat - y0 - loc.iy * ystep;
return loc;
}
real Grad(size_t i) const { return Grad(i % Nx(), i / Nx()); }
};
class Rect2DData: public BaseData
{
std::vector<real> lon, lat;
static real D(real lon1, real lat1, real lon2, real lat2) { return michlib::GCD(lon1 * M_PI / 180.0, lat1 * M_PI / 180.0, lon2 * M_PI / 180.0, lat2 * M_PI / 180.0) * 6371.0; }
public:
using BaseData::IsFill;
using BaseData::V;
@ -151,56 +87,4 @@ class Rect2DData: public BaseData
real Ix2Lon(size_t ix) const { return lon[ix]; }
real Iy2Lat(size_t iy) const { return lat[iy]; }
real dVdX(size_t ix, size_t iy) const
{
if(IsFill(ix, iy)) return Fillval();
if(ix == 0 || IsFill(ix - 1, iy))
{
if(IsFill(ix + 1, iy))
return Fillval();
else
return (V(ix + 1, iy) - V(ix, iy)) / D(Lon(ix, iy), Lat(ix, iy), Lon(ix + 1, iy), Lat(ix + 1, iy));
}
if(ix == Nx() - 1 || IsFill(ix + 1, iy))
{
if(IsFill(ix - 1, iy))
return Fillval();
else
return (V(ix, iy) - V(ix - 1, iy)) / D(Lon(ix - 1, iy), Lat(ix - 1, iy), Lon(ix, iy), Lat(ix, iy));
}
return 0.5 * ((V(ix + 1, iy) - V(ix, iy)) / D(Lon(ix, iy), Lat(ix, iy), Lon(ix + 1, iy), Lat(ix + 1, iy)) +
(V(ix, iy) - V(ix - 1, iy)) / D(Lon(ix - 1, iy), Lat(ix - 1, iy), Lon(ix, iy), Lat(ix, iy)));
}
real dVdY(size_t ix, size_t iy) const
{
if(IsFill(ix, iy)) return Fillval();
if(iy == 0 || IsFill(ix, iy - 1))
{
if(IsFill(ix, iy + 1))
return Fillval();
else
return (V(ix, iy + 1) - V(ix, iy)) / D(Lon(ix, iy), Lat(ix, iy), Lon(ix, iy + 1), Lat(ix, iy + 1));
}
if(iy == Ny() - 1 || IsFill(ix, iy + 1))
{
if(IsFill(ix, iy - 1))
return Fillval();
else
return (V(ix, iy) - V(ix, iy - 1)) / D(Lon(ix, iy - 1), Lat(ix, iy - 1), Lon(ix, iy), Lat(ix, iy));
}
return 0.5 * ((V(ix, iy + 1) - V(ix, iy)) / D(Lon(ix, iy), Lat(ix, iy), Lon(ix, iy + 1), Lat(ix, iy + 1)) +
(V(ix, iy) - V(ix, iy - 1)) / D(Lon(ix, iy - 1), Lat(ix, iy - 1), Lon(ix, iy), Lat(ix, iy)));
}
real Grad(size_t ix, size_t iy) const
{
real grx = dVdX(ix, iy);
real gry = dVdY(ix, iy);
if(grx == Fillval() || gry == Fillval()) return Fillval();
return michlib::Hypot(grx, gry);
}
real Grad(size_t i) const { return Grad(i % Nx(), i / Nx()); }
};

29
include/traits.h

@ -169,31 +169,8 @@ concept ReadIs1DGeoArray = requires {
};
template<class T>
concept ReadIs2DXYRectArray = requires {
concept CanInterpolate2D = requires {
{
std::declval<ReadType<T>>().Ix2X(0)
} -> std::convertible_to<real>;
{
std::declval<ReadType<T>>().Iy2Y(0)
} -> std::convertible_to<real>;
};
template<class T>
concept ReadIs2DXYArray = requires {
{
std::declval<ReadType<T>>().X(0, 0)
} -> std::convertible_to<real>;
{
std::declval<ReadType<T>>().Y(0, 0)
} -> std::convertible_to<real>;
};
template<class T>
concept ReadIs1DArray = requires {
{
std::declval<ReadType<T>>().X(0)
} -> std::convertible_to<real>;
{
std::declval<ReadType<T>>().Y(0)
} -> std::convertible_to<real>;
std::declval<ReadType<T>>().GridPoint(0.0, 0.0)
} -> std::convertible_to<struct GridPointLocation>;
};

178
include/zarr.h

@ -1,178 +0,0 @@
#pragma once
#include "GPL.h"
#include "cache.h"
#include "curlfuncs.h"
#include "nczarrcommon.h"
#include <json/json.h>
#include <variant>
class ZarrTypes: public NcZarrTypes
{
protected:
template<class VType> class ReadedData
{
//public:
using Vec = std::vector<size_t>;
private:
Vec start, chunkstart;
ArrCounter mainind, chunkind, inchunkind;
std::vector<std::unique_ptr<VType[]>> data;
public:
ReadedData(): mainind(Vec()), chunkind(Vec()), inchunkind(Vec()) {}
ReadedData(size_t N, const size_t* start, const size_t* count, const size_t* csize, std::vector<std::unique_ptr<VType[]>>&& d):
start(start, start + N),
chunkstart(
[](size_t N, const size_t* st, const size_t* cs)
{
Vec out(N);
for(size_t i = 0; i < N; i++) out[i] = st[i] / cs[i];
return out;
}(N, start, csize)),
mainind(Vec(count, count + N)),
chunkind(
[](size_t N, const size_t* st, const size_t* cn, const size_t* cs)
{
Vec out(N);
for(size_t i = 0; i < N; i++) out[i] = (st[i] + cn[i]) / cs[i] - st[i] / cs[i] + 1;
return out;
}(N, start, count, csize)),
inchunkind(Vec(csize, csize + N)),
data(std::move(d))
{
}
VType operator()(size_t lini) const
{
Vec ind = mainind.Index(lini, mainind.Count());
Vec cind(ind.size()), inind(ind.size());
for(size_t i = 0; i < ind.size(); i++)
{
cind[i] = (ind[i] + start[i]) / inchunkind.Count(i) - chunkstart[i]; // indes of chunk
inind[i] = (ind[i] + start[i]) % inchunkind.Count(i); // index inside chunk
}
size_t chunk = chunkind.Index(cind);
size_t inside = inchunkind.Index(inind);
return data[chunk][inside];
}
};
private:
// Create attribute from json value
static AttVT CreateAtt(const Json::Value& val)
{
if(val.type() == Json::intValue) return AttVT{std::in_place_type<int8>, val.asInt64()};
if(val.type() == Json::uintValue) return AttVT(std::in_place_type<uint8>, val.asUInt64());
if(val.type() == Json::realValue) return AttVT(std::in_place_type<double>, val.asDouble());
if(val.type() == Json::stringValue)
{
auto str = val.asString();
return AttVT(std::in_place_type<MString>, MString(str.c_str(), str.size()));
}
if(val.type() == Json::booleanValue) return AttVT(std::in_place_type<bool>, val.asBool());
return AttVT();
}
public:
// Read attributes from .zattrs
static auto ReadAtts(const Json::Value& obj)
{
std::vector<Attribute> out;
if(obj.type() != Json::objectValue) return out;
const auto keys = obj.getMemberNames();
for(const auto& key: keys)
if(key != "_ARRAY_DIMENSIONS") out.emplace_back(key, CreateAtt(obj[key]));
return out;
}
};
class ZarrFunctions: public ZarrTypes
{
std::unique_ptr<GenericCache> cache;
CURLRAII chandle;
MString url;
MString proxyurl;
std::vector<std::vector<size_t>> chunks;
// Find variable names in metadata
static std::vector<MString> ReadVarNames(const Json::Value& meta);
Error AddVar(const MString& name, const Json::Value& zattrs, const Json::Value& zarray);
protected:
ZarrFunctions()
{
auto oldprefix = michlib::GPL.UsePrefix("ZARR");
cache.reset(CreateCache(michlib::GPL.ParameterSValue("Cache", "")));
proxyurl = michlib::GPL.ParameterSValue("Proxy", "");
if(proxyurl.Exist()) curl_easy_setopt(chandle, CURLOPT_PROXY, proxyurl.Buf());
michlib::GPL.UsePrefix(oldprefix);
if(!cache)
{
michlib::errmessage("Can't init data cache");
cache.reset(new FakeCache);
}
}
template<class VType> RetVal<ReadedData<VType>> Read(const MString& var, const size_t* start, const size_t* count) const
{
using Vec = std::vector<size_t>;
size_t ind = FindInd(var, vars);
const size_t N = vars[ind].NDim();
const auto& csize = chunks[ind];
Vec chunkstart(
[](size_t N, const size_t* st, const size_t* cs)
{
Vec out(N);
for(size_t i = 0; i < N; i++) out[i] = st[i] / cs[i];
return out;
}(N, start, csize.data()));
ArrCounter chunkind(
[](size_t N, const size_t* st, const size_t* cn, const size_t* cs)
{
Vec out(N);
for(size_t i = 0; i < N; i++) out[i] = (st[i] + cn[i] - 1) / cs[i] - st[i] / cs[i] + 1;
return out;
}(N, start, count, csize.data()));
bool havefill = vars[ind].Fill().index() > 0;
VType fill = std::visit(
[](auto v)
{
if constexpr(std::is_convertible_v<decltype(v), VType>)
return static_cast<VType>(v);
else
return std::numeric_limits<VType>::max();
},
vars[ind].Fill());
std::vector<std::unique_ptr<VType[]>> cdata;
size_t chunksize = 1;
for(const auto c: csize) chunksize *= c;
cdata.resize(chunkind.N());
for(; chunkind; ++chunkind)
{
cdata[chunkind.Index()].reset(new VType[chunksize]);
auto res = GetChunk(var, chunkind.VIndex(chunkstart), chunksize, sizeof(VType), cdata[chunkind.Index()].get(), havefill ? &fill : nullptr);
if(!res) return res;
}
return ReadedData<VType>(N, start, count, csize.data(), std::move(cdata));
}
Error GetChunk(const MString& var, const std::vector<size_t>& chunkind, size_t chunksize, size_t elsize, void* data, const void* fill) const;
public:
Error Open(const MString& product, const MString& dataset, bool time = true);
};
using Zarr = NcZarrRead<ZarrFunctions>;

2
michlib

@ -1 +1 @@
Subproject commit f380988909fadd7f42c7ce09288c4ff3198ca318
Subproject commit a2105413f8a10e8695c85706487d4db5d2f54a61

6
sources/AVISO.h

@ -1,7 +1,7 @@
#pragma once
#include "layereddataz.h"
#include "layereddata.h"
class AVISOData: public LayeredDataZ
class AVISOData: public LayeredData
{
enum Type
{
@ -49,6 +49,6 @@ class AVISOData: public LayeredDataZ
return "Unknown dataset: " + dataset;
SetTitle(DataTitle());
return LayeredDataZ::Open(dataset);
return LayeredData::Open(dataset);
}
};

26
sources/AVISOLOCAL.cpp

@ -6,8 +6,7 @@ MString AVISOLOCALData::Info() const
if(!isOk()) return "";
NCFileA nc;
struct CoordNames cn;
struct DimNames dn;
struct CoordNames cn, dn;
std::set<MString> vars;
nc.Reset(datapath + "/uv-" + times[0].ToString() + ".nc");
@ -116,7 +115,28 @@ bool AVISOLOCALData::Read(const MString& vname, std::map<MString, AVISOLOCALData
}
if(!name.Exist()) // Conversion read
return TransformationRead(this, vname, cache, ip, i);
{
// U and U2 from u and v
if(vname == "U" || vname == "U2")
{
bool square = vname == "U2";
if(!(Read("u", cache, ip, i) && Read("v", cache, ip, i))) return false;
cache[vname] = cache.at("u").CopyGrid();
auto& U = cache.at(vname);
const auto& u = cache.at("u");
const auto& v = cache.at("v");
if(u.Unit().Exist()) U.SetUnit(square ? ("(" + u.Unit() + ")2") : u.Unit());
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 true;
}
return false;
}
// Direct read
Data data;

4
sources/AVISOLOCAL.h

@ -49,11 +49,11 @@ class AVISOLOCALData: public NCFuncs
return times[i];
}
time_t Timestep() const { return isOk() ? (times[1] - times[0]).Seconds() : 0; }
time_t Timestep() const { return isOk() ? (times[1] - times[0]) : 0; }
explicit operator bool() const { return times.size() > 0; }
VarPresence CheckVar(const MString& vname) const
bool CheckVar(const MString& vname) const
{
NCFileA nc;
nc.Reset(datapath + "/uv-" + times[0].ToString() + ".nc");

9
sources/BINFILE.h

@ -38,16 +38,11 @@ class BINFILEData
return times[i];
}
time_t Timestep() const { return isOk() ? (times[1] - times[0]).Seconds() : 0; }
time_t Timestep() const { return isOk() ? (times[1] - times[0]) : 0; }
explicit operator bool() const { return times.size() > 0; }
VarPresence CheckVar(const MString& vname) const
{
if(vname == "u" || vname == "v") return VarPresence::INTERNAL;
if(vname == "U" || vname == "U2") return VarPresence::DERIVED;
return VarPresence::NONE;
}
bool CheckVar(const MString& vname) const { return vname == "u" || vname == "v" || vname == "U" || vname == "U2"; }
bool Read(const MString& vname, std::map<MString, Data>& cache, size_t i) const;
};

222
sources/COPERNICUS.cpp

@ -1,222 +0,0 @@
#define MICHLIB_NOSOURCE
#include "COPERNICUS.h"
#include "mirrorfuncs.h"
#include <libxml/parser.h>
#include <libxml/tree.h>
using michlib::GPL;
RetVal<std::vector<struct FileInfo>> COPERNICUSData::ReadRemoteFileList(const MString& url) const
{
const static MString pref = "COPERNICUSData::ReadRemoteFileList";
LIBXML_TEST_VERSION
std::vector<struct FileInfo> out;
MString bucket, prefix;
// Split url on prefix and bucket
{
size_t pos = url.Len();
size_t count = 0;
for(size_t i = 0; i < url.Len(); i++)
{
if(url[i] == '/') count++;
if(count == 4)
{
pos = i;
break;
}
}
if(pos == url.Len()) return {pref, "Can't parse url: " + url};
bucket = url.SubStr(1, pos);
prefix = url.SubStr(pos + 2, url.Len() - pos - 1);
}
MString cont;
bool next = true;
CURLRAII chandle;
while(next)
{
MString url = bucket + "?list-type=2&prefix=" + prefix;
if(cont.Exist()) url += "&continuation-token=" + cont;
cont = "";
auto [data, res] = GetUrl(chandle, url);
if(res != CURLE_OK) return {pref, MString("Can't download ") + url + ": " + chandle.Err()};
xmlDocPtr doc = xmlReadMemory(data.Buf(), data.Len(), "data.xml", nullptr, 0);
if(doc == nullptr) return {pref, MString("Can't download ") + url + ": XML parse error"};
auto cur = xmlDocGetRootElement(doc);
if(cur == nullptr)
{
xmlFreeDoc(doc);
return {pref, MString("Can't download ") + url + ": empty XML"};
}
if(xmlStrEqual(cur->name, (const xmlChar*)"ListBucketResult") == 0)
{
xmlFreeDoc(doc);
return {pref, MString("Can't download ") + url + ": unknown XML"};
}
for(const auto* n = cur->children; n; n = n->next)
{
if(xmlStrEqual(n->name, (const xmlChar*)"NextContinuationToken") == 1)
{
auto* content = xmlNodeGetContent(n);
cont = (char*)content;
xmlFree(content);
}
if(xmlStrEqual(n->name, (const xmlChar*)"Contents") == 1)
{
MString fname;
MDateTime mtime;
size_t size = 0;
for(const auto* c = n->children; c; c = c->next)
{
if(xmlStrEqual(c->name, (const xmlChar*)"Key") == 1)
{
auto* content = xmlNodeGetContent(c);
fname = (char*)content;
xmlFree(content);
}
if(xmlStrEqual(c->name, (const xmlChar*)"LastModified") == 1)
{
auto* content = xmlNodeGetContent(c);
mtime.FromString((char*)content);
xmlFree(content);
}
if(xmlStrEqual(c->name, (const xmlChar*)"Size") == 1)
{
auto* content = xmlNodeGetContent(c);
size = MString((char*)content).ToInteger<size_t>();
xmlFree(content);
}
}
out.emplace_back(bucket + "/" + fname, fname.SubStr(prefix.Len() + 2, fname.Len() - prefix.Len() - 1), mtime, size);
}
}
xmlFreeDoc(doc);
next = cont.Exist();
}
std::sort(out.begin(), out.end(), [](const struct FileInfo& a, const struct FileInfo& b) { return a.name < b.name; });
return out;
}
Error COPERNICUSData::Mirror(const CLArgs& args) const
{
const static MString pref = "COPERNICUSData::Mirror";
GPL.UsePrefix("COPERNICUS");
// Local directory
MString mirrorroot = GPL.ParameterSValue("MirrorTo", "");
if(!mirrorroot.Exist()) return {pref, "Local mirror directory not specified"};
if(!args.contains("product")) return {pref, "Copernicus product not specified"};
MString prod = args.at("product");
CopernicusCatalog cat;
std::vector<MString> dsets;
if(args.contains("dataset"))
dsets.push_back(args.at("dataset"));
else
{
auto dlist = cat.DatasetList(prod);
if(!dlist) return dlist.Add(pref, "Can't get list of datasets");
dsets = dlist.Value();
}
michlib::RegExpSimple filter((args.contains("filter") ? args.at("filter") : ".*").Buf());
if(filter.Compile() != 0) return Error(pref, MString("Can't compile regular expression ") + filter.RegStr());
CURLRAII chandle;
for(const auto& dset: dsets)
{
michlib::message("Mirroring " + dset);
auto url = cat.DatasetNativeURL(prod, dset);
if(!url) return {pref, "Can't find data for dataset " + dset + " from product " + prod};
MString locroot = mirrorroot + "/" + prod + "/" + dset;
auto lfilesret = ReadLocalFileList(locroot);
if(!lfilesret) return lfilesret.Add(pref, "Can't get local file list");
const auto& lfiles = lfilesret.Value();
auto rfilesret = ReadRemoteFileList(url.Value());
if(!rfilesret) return rfilesret.Add(pref, "Can't get remote file list");
const auto& rfiles = rfilesret.Value();
std::vector<size_t> down, rem;
std::vector<std::pair<size_t, size_t>> upd;
{
size_t rpos = 0, lpos = 0;
while(rpos != rfiles.size() || lpos != lfiles.size())
{
if(rpos == rfiles.size())
while(lpos != lfiles.size())
{
if(filter.Match(lfiles[lpos].name.Buf())) rem.push_back(lpos);
lpos++;
}
if(lpos == lfiles.size())
while(rpos != rfiles.size())
{
if(filter.Match(rfiles[rpos].name.Buf())) down.push_back(rpos);
rpos++;
}
if(rpos == rfiles.size() || lpos == lfiles.size()) continue;
if(rfiles[rpos].name < lfiles[lpos].name)
{
if(filter.Match(rfiles[rpos].name.Buf())) down.push_back(rpos);
rpos++;
}
else if(lfiles[lpos].name < rfiles[rpos].name)
{
if(filter.Match(lfiles[lpos].name.Buf())) rem.push_back(lpos);
lpos++;
}
else
{
auto delta = rfiles[rpos].mtime.Epoch() - lfiles[lpos].mtime.Epoch();
if(delta < 0) delta = -delta;
if((delta > 0 || rfiles[rpos].size != lfiles[lpos].size) && filter.Match(lfiles[lpos].name.Buf())) upd.emplace_back(rpos, lpos);
lpos++;
rpos++;
}
}
}
michlib::message(MString("New files: ") + down.size());
michlib::message(MString("Obsolete files: ") + rem.size());
michlib::message(MString("Modified files: ") + upd.size());
for(size_t i = 0; i < down.size(); i++)
{
size_t ri = down[i];
auto err = DownloadFile(chandle, rfiles[ri], locroot);
if(!err) return err.Add(pref, "Can't download file");
}
for(size_t i = 0; i < rem.size(); i++)
{
size_t li = rem[i];
auto err = RemoveFile(lfiles[li]);
if(!err) return err.Add(pref, "Can't remove file");
}
for(size_t i = 0; i < upd.size(); i++)
{
size_t ri = upd[i].first;
size_t li = upd[i].second;
auto err = UpdateFile(chandle, rfiles[ri], lfiles[li], locroot);
if(!err) return err.Add(pref, "Can't update file");
}
}
return Error();
}

21
sources/COPERNICUS.h

@ -1,21 +0,0 @@
#pragma once
#include "ParseArgs.h"
#include "copcat.h"
#include "mdatetime.h"
using michlib::MDateTime;
using michlib::MString;
class COPERNICUSData
{
// Get remote file list from url
RetVal<std::vector<struct FileInfo>> ReadRemoteFileList(const MString& url) const;
public:
static constexpr const char* name = "COPERNICUS";
COPERNICUSData() = default;
// Main mirror function
Error Mirror(const CLArgs& args) const;
};

86
sources/GRIDVEL.cpp

@ -1,86 +0,0 @@
#define MICHLIB_NOSOURCE
#include "GRIDVEL.h"
MString GRIDVELData::Info() const
{
if(!isOk()) return "";
// clang-format off
return MString() +
" Region: (" + u.Xb() + " : " + u.Xe() + ") x (" + u.Yb() + " : " + u.Ye() + ")\n" +
" Grid: " + u.Nx() + "x" + u.Ny() + "\n" +
" Supported variables: u, v, U2";
// clang-format on
}
MString GRIDVELData::Open(const CLArgs& args)
{
MString uname = args.contains("u") ? args.at("u") : "";
MString vname = args.contains("v") ? args.at("v") : "";
if(!uname.Exist()) return "File with u component not specified";
if(!vname.Exist()) return "File with v component not specified";
unit = args.contains("unit") ? args.at("unit") : "cm/s";
fill = args.contains("fill") ? args.at("fill").ToReal() : 1e10;
u.Open(uname);
if(!u.Opened()) return "Can't open file: " + uname;
v.Open(vname);
if(!v.Opened()) return "Can't open file: " + vname;
if(u != v) return "Files " + uname + " and " + vname + " have different grids";
return "";
}
bool GRIDVELData::Read(const MString& vname, std::map<MString, GRIDVELData::Data>& cache, size_t i) const
{
if(cache.contains(vname)) return true;
if(!isOk()) return false;
// Only rectangular grids are supported
real xs = (u.Xe() - u.Xb()) / (u.Nx() - 1);
real ys = (u.Ye() - u.Yb()) / (u.Ny() - 1);
Data out(u.Nx(), u.Ny(), u.Xb(), u.Yb(), xs, ys, MString(unit));
// U and U2 from u and v
if(vname == "U" || vname == "U2")
{
bool square = vname == "U2";
if(!(Read("u", cache, i) && Read("v", cache, i))) return false;
cache[vname] = cache.at("u").CopyGrid();
auto& U = cache.at(vname);
const auto& udata = cache.at("u");
const auto& vdata = cache.at("v");
if(udata.Unit().Exist()) U.SetUnit(square ? ("(" + udata.Unit() + ")2") : udata.Unit());
for(size_t ind = 0; ind < U.N(); ind++)
{
if(udata.IsFill(ind) || vdata.IsFill(ind))
U.V(ind) = U.Fillval();
else
U.V(ind) = square ? (udata(ind) * udata(ind) + vdata(ind) * vdata(ind)) : michlib::Hypot(udata(ind), vdata(ind));
}
return true;
}
if(vname == "u" || vname == "v")
{
bool isu = vname == "u";
for(IType ix = 0; ix < u.Nx(); ix++)
for(IType iy = 0; iy < u.Ny(); iy++)
{
if(isu ? (u(ix, iy) == NAN || u(ix, iy) >= 1e10) : (v(ix, iy) == NAN || v(ix, iy) >= 1e10))
out.V(ix, iy) = out.Fillval();
else
out.V(ix, iy) = isu ? u(ix, iy) : v(ix, iy);
}
if(out)
{
cache[vname] = std::move(out);
return true;
}
}
return false;
}

50
sources/GRIDVEL.h

@ -1,50 +0,0 @@
#pragma once
#include "DataAdapters/gridfile.h"
#include "mdatetime.h"
#include "simple2ddata.h"
using michlib::MDateTime;
class GRIDVELData
{
michlib::GridFile u,v;
MString unit;
real fill;
using IType=decltype(u.Nx());
public:
static constexpr const char* name = "GRIDVEL";
static constexpr const char* disabledactions = "genintfile";
using Data = Simple2DData;
GRIDVELData() = default;
MString Info() const;
// TODO: RetVal
MString Open(const CLArgs& args);
bool isOk() const { return u.Opened() &&v.Opened(); }
size_t NTimes() const { return 1; }
MDateTime Time(size_t i) const
{
return MDateTime();
}
//time_t Timestep() const { return isOk() ? (times[1] - times[0]) : 0; }
explicit operator bool() const { return u.Opened() &&v.Opened(); }
VarPresence CheckVar(const MString& vname) const
{
if(vname == "u" || vname == "v") return VarPresence::INTERNAL;
if(vname == "U" || vname == "U2") return VarPresence::DERIVED;
return VarPresence::NONE;
}
bool Read(const MString& vname, std::map<MString, Data>& cache, size_t i) const;
};

6
sources/HYCOM.h

@ -8,7 +8,6 @@ class HYCOMData: public LayeredData
TYPE_UNKNOWN,
TYPE_REANALYSIS,
TYPE_HINDCAST,
TYPE_NRT,
TYPE_FORECAST
};
@ -25,8 +24,7 @@ class HYCOMData: public LayeredData
{
case(TYPE_REANALYSIS): return "GOFS 3.1: 41-layer HYCOM + NCODA Global 1/12 Reanalysis";
case(TYPE_HINDCAST): return "GOFS 3.1: 41-layer HYCOM + NCODA Global 1/12 Analysis Hindcast";
case(TYPE_NRT): return "ESPC-D-V02: Global 1/12 Analysis Archive";
case(TYPE_FORECAST): return "ESPC-D-V02: Global 1/12 Forecast";
case(TYPE_FORECAST): return "GOFS 3.1: 41-layer HYCOM + NCODA Global 1/12 Analysis Forecast";
default: return "No title";
}
}
@ -39,8 +37,6 @@ class HYCOMData: public LayeredData
GPL.UsePrefix("HYCOM");
if(dataset == "Forecast")
type = TYPE_FORECAST;
else if(dataset == "NRT")
type = TYPE_NRT;
else if(dataset == "Hindcast")
type = TYPE_HINDCAST;
else if(dataset == "Reanalysis")

7
sources/MODISBINLOCAL.h

@ -54,12 +54,11 @@ class MODISBINLOCALData
std::pair<const BaseParameters*, MString> Parameters(michlib_internal::ParameterListEx& pars, const CLArgs& args, const struct Region& reg) const;
VarPresence CheckVar(const MString& vname) const
bool CheckVar(const MString& vname) const
{
if(dataset.empty()) return VarPresence::NONE;
if(dataset.empty()) return false;
bool ischl = dataset.front() == "A_CHL" || dataset.front() == "T_CHL";
if((vname == "chl" && ischl) || (vname == "temp" && !ischl)) return VarPresence::INTERNAL;
return VarPresence::NONE;
return (vname == "chl" && ischl) || (vname == "temp" && !ischl);
}
bool isOk() const { return times.size() > 0; }

56
sources/NEMO.h

@ -1,26 +1,14 @@
#pragma once
#include "layereddataz.h"
#include "layereddata.h"
class NEMOData: public LayeredDataZ
class NEMOData: public LayeredData
{
enum Type
{
TYPE_UNKNOWN,
TYPE_DT,
TYPE_DT1,
TYPE_NRT,
TYPE_NRT6,
TYPE_BALTICDT,
TYPE_BALTICNRT,
TYPE_BALTICNRT1,
TYPE_BLKSEADT,
TYPE_BLKSEANRT,
TYPE_MEDSEADT,
TYPE_MEDSEANRT,
TYPE_BISCDT,
TYPE_BISCNRT,
TYPE_ENWSDT,
TYPE_ENWSNRT
TYPE_NRT6
};
Type type = TYPE_UNKNOWN;
@ -35,20 +23,8 @@ class NEMOData: public LayeredDataZ
switch(type)
{
case(TYPE_DT): return "NEMO Delayed time, daily mean (DT)";
case(TYPE_DT1): return "NEMO Delayed time, daily mean, part 2 (DT1)";
case(TYPE_NRT): return "NEMO Near-real time, daily mean (NRT)";
case(TYPE_NRT6): return "NEMO Near-real time, 6h resolution (NRT6)";
case(TYPE_BALTICDT): return "NEMO Delayed time, Baltic region, daily mean (BALTICDT)";
case(TYPE_BALTICNRT): return "NEMO Near-real time, Baltic region, daily mean (BALTICNRT)";
case(TYPE_BALTICNRT1): return "NEMO Near-real time, Baltic region, 1h resolution (BALTICNRT1)";
case(TYPE_BLKSEADT): return "NEMO Delayed time, Black Sea region, daily mean (BLKSEADT)";
case(TYPE_BLKSEANRT): return "NEMO Near-real time time, Black Sea region, daily mean (BLKSEANRT)";
case(TYPE_MEDSEADT): return "NEMO Delayed time, Mediterranean Sea region, daily mean (MEDSEADT)";
case(TYPE_MEDSEANRT): return "NEMO Near-real time, Mediterranean Sea region, daily mean (MEDSEANRT)";
case(TYPE_BISCDT): return "NEMO Delayed time, Atlantic-Iberian Biscay Irish region, daily mean (BISCDT)";
case(TYPE_BISCNRT): return "NEMO Near-real time, Atlantic-Iberian Biscay Irish region, daily mean (BISCNRT)";
case(TYPE_ENWSDT): return "NEMO Delayed time, Atlantic - European North West Shelf region, daily mean (ENWSDT)";
case(TYPE_ENWSNRT): return "NEMO Near-real time, Atlantic - European North West Shelf region, daily mean (ENWSNRT)";
default: return "No title";
}
}
@ -61,38 +37,14 @@ class NEMOData: public LayeredDataZ
GPL.UsePrefix("NEMO");
if(dataset == "DT")
type = TYPE_DT;
else if(dataset == "DT1")
type = TYPE_DT1;
else if(dataset == "NRT")
type = TYPE_NRT;
else if(dataset == "NRT6")
type = TYPE_NRT6;
else if(dataset == "BALTICDT")
type = TYPE_BALTICDT;
else if(dataset == "BALTICNRT")
type = TYPE_BALTICNRT;
else if(dataset == "BALTICNRT1")
type = TYPE_BALTICNRT1;
else if(dataset == "BLKSEADT")
type = TYPE_BLKSEADT;
else if(dataset == "BLKSEANRT")
type = TYPE_BLKSEANRT;
else if(dataset == "MEDSEADT")
type = TYPE_MEDSEADT;
else if(dataset == "MEDSEANRT")
type = TYPE_MEDSEANRT;
else if(dataset == "BISCDT")
type = TYPE_BISCDT;
else if(dataset == "BISCNRT")
type = TYPE_BISCNRT;
else if(dataset == "ENWSDT")
type = TYPE_ENWSDT;
else if(dataset == "ENWSNRT")
type = TYPE_ENWSNRT;
else
return "Unknown dataset: " + dataset;
SetTitle(DataTitle());
return LayeredDataZ::Open(dataset);
return LayeredData::Open(dataset);
}
};

6
sources/NEMOBIO.h

@ -1,7 +1,7 @@
#pragma once
#include "layereddataz.h"
#include "layereddata.h"
class NEMOBIOData: public LayeredDataZ
class NEMOBIOData: public LayeredData
{
enum Type
{
@ -43,6 +43,6 @@ class NEMOBIOData: public LayeredDataZ
return "Unknown dataset: " + dataset;
SetTitle(DataTitle());
return LayeredDataZ::Open(dataset);
return LayeredData::Open(dataset);
}
};

129
sources/TSCDATA.cpp

@ -1,129 +0,0 @@
#define MICHLIB_NOSOURCE
#include "TSCDATA.h"
MString TSCDATAData::Open(const CLArgs& args)
{
if(!args.contains("dataset")) return "path to data not specified";
MString dataset = args.at("dataset");
michlib::NCFileA newnc;
std::vector<MString> newvnames, newlnames;
MString newhistory;
newnc.Reset(dataset);
if(!newnc) return "Can't open file " + dataset;
auto head = newnc.Header();
if(head.Dimensions().size() != 2) return "Unsupported number of dimensions";
if((head.Dimensions()[0].Name() != "longitude" || head.Dimensions()[1].Name() != "latitude") &&
(head.Dimensions()[1].Name() != "longitude" || head.Dimensions()[0].Name() != "latitude"))
return "Unsupported dimensions names";
if(head.Dimensions()[0].Name() == "longitude")
{
nx = head.Dimensions()[0].Len();
ny = head.Dimensions()[1].Len();
}
else
{
ny = head.Dimensions()[0].Len();
nx = head.Dimensions()[1].Len();
}
{
bool lonfound = false, latfound = false;
for(const auto& v: head.Variables())
if(v.Dimensions().size() == 1 && v.Type().Id() == NC_FLOAT)
{
lonfound = lonfound || (v.Dimensions()[0].Name() == "longitude" && v.Name() == "longitude");
latfound = latfound || (v.Dimensions()[0].Name() == "latitude" && v.Name() == "latitude");
}
if(!lonfound) return "Longitude not found";
if(!latfound) return "Latitude not found";
}
for(const auto& v: head.Variables())
{
if(v.Dimensions().size() != 2) continue;
if(v.Type().Id() != NC_FLOAT) continue;
if((v.Dimensions()[0].Name() != "longitude" || v.Dimensions()[1].Name() != "latitude") && (v.Dimensions()[1].Name() != "longitude" || v.Dimensions()[0].Name() != "latitude"))
continue;
newvnames.push_back(v.Name());
auto lname = newnc.A<MString>(v.Name(), "long_name");
newlnames.push_back(lname ? lname.Get() : "");
}
if(newvnames.size() == 0) return "No variables found";
{
auto his = newnc.A<MString>("history");
if(his) newhistory = his;
}
history = std::move(newhistory);
vnames = std::move(newvnames);
lnames = std::move(newlnames);
nc = std::move(newnc);
return "";
}
MString TSCDATAData::Info() const
{
if(!nc) return "";
MString out;
out += MString("Dimensions: ") + nx + " X " + ny + "\n";
out += MString("Variables: ");
for(size_t i = 0; i < vnames.size(); i++) out += ((i == 0) ? "" : ", ") + vnames[i];
out += "\n";
auto his = nc.A<MString>("history");
if(his) out += "Creator: " + his.Get() + "\n";
return out;
}
std::vector<TSCDATAData::DataType> TSCDATAData::ReadLons() const
{
std::vector<DataType> out;
auto lons = nc.V<DataType>("longitude");
if(lons)
{
out.resize(lons.DimLen(0));
for(size_t i = 0; i < out.size(); i++) out[i] = lons(i);
}
return out;
}
std::vector<TSCDATAData::DataType> TSCDATAData::ReadLats() const
{
std::vector<DataType> out;
auto lats = nc.V<DataType>("latitude");
if(lats)
{
out.resize(lats.DimLen(0));
for(size_t i = 0; i < out.size(); i++) out[i] = lats(i);
}
return out;
}
std::vector<TSCDATAData::DataType> TSCDATAData::ReadVar(const MString& name) const
{
std::vector<DataType> out;
bool havevar = false;
for(size_t i = 0; i < vnames.size(); i++) havevar = havevar || (vnames[i] == name);
if(!havevar) return out;
auto var = nc.V<DataType>(name, "latitude", "longitude");
if(var)
{
out.resize(nx * ny);
for(size_t iy = 0; iy < ny; iy++)
for(size_t ix = 0; ix < nx; ix++) out[iy * nx + ix] = var(iy, ix);
}
return out;
}
TSCDATAData::DataType TSCDATAData::FillVal(const MString& name) const
{
auto fill = nc.A<DataType>(name, "_FillValue");
return fill ? fill.Get() : 0.0;
}

35
sources/TSCDATA.h

@ -1,35 +0,0 @@
#pragma once
#include "DataAdapters/ncfilealt.h"
#include "ParseArgs.h"
#include "simple2ddata.h"
class TSCDATAData
{
michlib::NCFileA nc;
std::vector<MString> vnames, lnames;
size_t nx, ny;
MString history;
using DataType = float;
public:
static constexpr const char* name = "TSCDATA";
MString Info() const;
MString Open(const CLArgs& args);
std::vector<DataType> ReadLons() const;
std::vector<DataType> ReadLats() const;
std::vector<DataType> ReadVar(const MString& name) const;
const auto& VarNames() const { return vnames; }
const auto& LongNames() const { return lnames; }
size_t Nx() const { return nx; }
size_t Ny() const { return ny; }
size_t NVar() const { return vnames.size(); }
const auto& History() const { return history; }
DataType FillVal(const MString& name) const;
};

526
sources/VYLET.cpp

@ -1,526 +0,0 @@
#define MICHLIB_NOSOURCE
#include "VYLET.h"
MString VYLETData::Info() const
{
if(!vylet) return "";
MString out;
michlib::CompiledParser xy2lon, xy2lat;
real x, y;
michlib::ParserVars pv;
pv["x"] = &x;
pv["y"] = &y;
vylet->UsePrefix("Datafile_Info");
MString xy2lonstr = vylet->ParameterSValue("xy2lon", "%y");
MString xy2latstr = vylet->ParameterSValue("xy2lat", "%x");
ArifmeticCompiler(xy2lonstr, xy2lon, &pv);
ArifmeticCompiler(xy2latstr, xy2lat, &pv);
real lonb, latb, lone, late;
vylet->UsePrefix("");
x = vylet->ParameterRValue("x0", 0.0);
y = vylet->ParameterRValue("y0", 0.0);
xy2lon.Run(lonb);
xy2lat.Run(latb);
x = vylet->ParameterRValue("x1", 0.0);
y = vylet->ParameterRValue("y1", 0.0);
xy2lon.Run(lone);
xy2lat.Run(late);
out += "Start time: " + start.ToString() + "\n";
out += "End time: " + end.ToString() + " " + (invtime ? "(backward integration)" : "(forward integration)") + "\n";
out += "Region: (" + MString(lonb) + " : " + lone + ") x (" + latb + " : " + late + ")\n";
out += "Grid:" + MString(" ") + lons.size() + "x" + lats.size() + "\n";
out += HasCoast() ? "Coast: checked\n" : "Coast: not checked\n";
out += LengthFast() ? "Trajectory length: fast calculation\n" : "Trajectory length: exact calculation\n";
out += "Borders: ";
bool needcomma = false;
if(Left() >= 0.0)
{
real lon;
if(needcomma) out += ", ";
out += "left=";
x = Left();
xy2lon.Run(lon);
out += lon;
needcomma = true;
}
if(Right() <= maxx)
{
real lon;
if(needcomma) out += ", ";
out += "right=";
x = Right();
xy2lon.Run(lon);
out += lon;
needcomma = true;
}
if(Down() >= 0.0)
{
real lat;
if(needcomma) out += ", ";
out += "bottom=";
y = Down();
xy2lat.Run(lat);
out += lat;
needcomma = true;
}
if(Up() <= maxy)
{
real lat;
if(needcomma) out += ", ";
out += "bottom=";
y = Up();
xy2lat.Run(lat);
out += lat;
needcomma = true;
}
if(!needcomma) out += "no";
out += "\n";
MString vars = "vylD";
if(HasLyap()) vars += ", vylL";
if(HasTime()) vars += ", vylT";
vars += ", vylNx, vylNy, vylRx, vylRy, vylEx, vylEy, vylPhip, vylPhim, vylPhit";
if(HasLyap()) vars += ", vyldS";
vars += ", vylAngle, vylLen";
if(HasTime()) vars += ", vylTmask";
out += "Supported variables: " + vars + "\n";
return out;
}
MString VYLETData::Open(const CLArgs& args)
{
if(!args.contains("dataset")) return "path to data not specified";
MString dataset = args.at("dataset");
decltype(vylet) nvylet;
michlib::RegExpSimple havex("%x"), havey("%y");
nvylet.reset(new michlib::BFileR);
if(nvylet->Open(dataset) != ERR_NOERR) return "Can't open file " + dataset;
nvylet->UsePrefix("ProgramInfo");
if(nvylet->ParameterSValue("Task", "") != "AdvInt:Vylet") return "File " + dataset + " is not vylet file";
nvylet->UsePrefix("");
if(nvylet->ParameterSValue("nettype", "") != "SQUARE") return "File " + dataset + " have unsupported net type";
MString method = nvylet->ParameterSValue("Method", "");
if(!(method == "Bicubic" || method == "BicubicL" || method == "BicubicI" || method == "BicubicIL")) return "File " + dataset + " have unsupported integration method";
invtime = (method == "BicubicI" || method == "BicubicIL");
nvylet->UsePrefix("Datafile_Info");
MString xy2lonstr = nvylet->ParameterSValue("xy2lon", "%y");
MString xy2latstr = nvylet->ParameterSValue("xy2lat", "%x");
if(havey.Match(xy2lonstr.Buf()) || havex.Match(xy2latstr.Buf())) return "File " + dataset + " have unsupported grid";
auto res = ref.FromString(nvylet->ParameterSValue(invtime ? "EndDate" : "BeginDate", ""));
if(!res) return "Can't read reference time";
nvylet->UsePrefix("");
start = R2Time(nvylet->ParameterRValue("tbeg", 0.0));
end = R2Time(nvylet->ParameterRValue("tmax", 0.0));
nvylet->UsePrefix("Datafile");
auto dx = nvylet->ParameterRValue("dx", 0.0);
auto dy = nvylet->ParameterRValue("dy", 0.0);
auto nx = nvylet->ParameterUValue("nx", 0);
auto ny = nvylet->ParameterUValue("ny", 0);
maxx = dx * (nx - 1);
maxy = dy * (ny - 1);
michlib::CompiledParser xy2lon, xy2lat;
real x, y;
michlib::ParserVars pv;
pv["x"] = &x;
pv["y"] = &y;
ArifmeticCompiler(xy2lonstr, xy2lon, &pv);
ArifmeticCompiler(xy2latstr, xy2lat, &pv);
nvylet->UsePrefix("");
auto nlon = nvylet->ParameterUValue("Nx", 0) + 1;
auto nlat = nvylet->ParameterUValue("Ny", 0) + 1;
lons.resize(nlon);
lats.resize(nlat);
elon.resize(nlon * nlat);
elat.resize(nlon * nlat);
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++)
{
x = (*nvylet)[2][iy * lons.size() + ix];
y = (*nvylet)[3][iy * lons.size() + ix];
xy2lon.Run(elon[iy * lons.size() + ix]);
xy2lat.Run(elat[iy * lons.size() + ix]);
}
for(size_t ix = 0; ix < nlon; ix++)
{
x = (*nvylet)[0][ix];
y = (*nvylet)[1][ix];
xy2lon.Run(lons[ix]);
}
for(size_t iy = 0; iy < nlat; iy++)
{
x = (*nvylet)[0][iy * nlon];
y = (*nvylet)[1][iy * nlon];
xy2lat.Run(lats[iy]);
}
vylet = std::move(nvylet);
return "";
}
bool VYLETData::Read(const MString& vname, std::map<MString, VYLETData::Data>& cache, size_t tind) const
{
if(tind != 0) return false;
if(cache.contains(vname)) return true;
Data out;
if(vname == "vylD") out = ReadD();
if(vname == "vylL") out = ReadL();
if(vname == "vylT") out = ReadT();
if(vname == "vylNx") out = ReadNx();
if(vname == "vylNy") out = ReadNy();
if(vname == "vylRx") out = ReadRx();
if(vname == "vylRy") out = ReadRy();
if(vname == "vylEx") out = ReadEx();
if(vname == "vylEy") out = ReadEy();
if(vname == "vylPhip") out = ReadPhip();
if(vname == "vylPhim") out = ReadPhim();
if(vname == "vylPhit") out = ReadPhit();
if(vname == "vyldS") out = ReaddS();
if(vname == "vylAngle") out = ReadAngle();
if(vname == "vylLen") out = ReadLen();
if(vname == "vylTmask") out = ReadTmask();
if(!out) return false;
cache[vname] = std::move(out);
return true;
}
VYLETData::Data VYLETData::ReadD() const
{
Data out(lons, lats);
if(!vylet) return Data();
const real xl = Left();
const real xr = Right();
const real yd = Down();
const real yu = Up();
real x, y;
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++)
{
out(ix, iy) = 0.0;
x = (*vylet)[2][iy * lons.size() + ix];
y = (*vylet)[3][iy * lons.size() + ix];
if(yd > 0.0 && y < yd) out(ix, iy) = -1.0;
if(xl > 0.0 && x < xl) out(ix, iy) = -2.0;
if(yu < maxy && y > yu) out(ix, iy) = -3.0;
if(xr < maxx && x > xr) out(ix, iy) = -4.0;
if(out(ix, iy) >= 0.0)
out(ix, iy) = 6371.0 * michlib::GCD(M_PI * lons[ix] / 180.0, M_PI * lats[iy] / 180.0, M_PI * elon[iy * lons.size() + ix] / 180.0, M_PI * elat[iy * lons.size() + ix] / 180.0);
}
out.SetUnit("km");
out.SetLongName("Distance between start and end points");
out.SetComment("Special values: -1.0 - trajectory leave region via south border, -2.0 - trajectory leave region via west border, -3.0 - trajectory leave region via north border, "
"-4.0 - trajectory leave region via east border");
return out;
}
VYLETData::Data VYLETData::ReadL() const
{
Data out(lons, lats);
if(!vylet) return Data();
auto lcol = Name2ColNum("Log(G.sigma1)");
auto tcol = Name2ColNum("time");
if(lcol == 0 || tcol == 0) return Data();
MDateTime time;
real lambda, days;
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++)
{
time = R2Time((*vylet)[tcol - 1][iy * lons.size() + ix]);
lambda = (*vylet)[lcol - 1][iy * lons.size() + ix];
days = (time - start).D();
out(ix, iy) = lambda / days;
}
out.SetUnit("days-1");
out.SetLongName("Lyapunov exponent");
return out;
}
VYLETData::Data VYLETData::ReadT() const
{
Data out(lons, lats);
if(!vylet) return Data();
auto tcol = Name2ColNum("time");
if(tcol == 0) return Data();
const real xl = Left();
const real xr = Right();
const real yd = Down();
const real yu = Up();
vylet->UsePrefix("");
const real acc = vylet->ParameterRValue("accuracy", 1.0);
const real tstep = 2.0 * M_PI * 1000.0 / acc;
const real maxdays = (end - start).D();
MDateTime time;
real days;
real x, y;
bool inside, maxtime;
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++)
{
x = (*vylet)[2][iy * lons.size() + ix];
y = (*vylet)[3][iy * lons.size() + ix];
time = R2Time((*vylet)[tcol - 1][iy * lons.size() + ix]);
days = (time - start).D();
if(days <= tstep * 1.5) days = 0.0;
inside = x > xl && x < xr && y > yd && y < yu;
maxtime = days >= maxdays - tstep * 0.5;
if(maxtime) days = maxdays;
if(inside && !maxtime) days = -days;
out(ix, iy) = days;
}
out.SetUnit("days");
out.SetLongName("Time to reach border or coast");
out.SetComment("Special values: 0.0 - initial point on the land, " + MString(maxdays) + " - trajectory don't reach border, negative values - trajectory beached on the coast");
return out;
}
VYLETData::Data VYLETData::ReadNx() const
{
Data out(lons, lats);
if(!vylet) return Data();
auto ncol = Name2ColNum("nx=0");
if(ncol == 0) return Data();
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++) out(ix, iy) = (*vylet)[ncol - 1][iy * lons.size() + ix];
out.SetLongName("Number of moments u=0");
return out;
}
VYLETData::Data VYLETData::ReadNy() const
{
Data out(lons, lats);
if(!vylet) return Data();
auto ncol = Name2ColNum("ny=0");
if(ncol == 0) return Data();
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++) out(ix, iy) = (*vylet)[ncol - 1][iy * lons.size() + ix];
out.SetLongName("Number of moments v=0");
return out;
}
VYLETData::Data VYLETData::ReadRx() const
{
Data out(lons, lats);
if(!vylet) return Data();
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++) out(ix, iy) = elon[iy * lons.size() + ix] - lons[ix];
out.SetLongName("Displacement in zonal direction");
return out;
}
VYLETData::Data VYLETData::ReadRy() const
{
Data out(lons, lats);
if(!vylet) return Data();
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++) out(ix, iy) = elat[iy * lons.size() + ix] - lats[iy];
out.SetLongName("Displacement in meridional direction");
return out;
}
VYLETData::Data VYLETData::ReadEx() const
{
Data out(lons, lats);
if(!vylet) return Data();
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++) out(ix, iy) = elon[iy * lons.size() + ix];
out.SetLongName("Final longitude");
return out;
}
VYLETData::Data VYLETData::ReadEy() const
{
Data out(lons, lats);
if(!vylet) return Data();
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++) out(ix, iy) = elat[iy * lons.size() + ix];
out.SetLongName("Final latitude");
return out;
}
VYLETData::Data VYLETData::ReadPhip() const
{
Data out(lons, lats);
if(!vylet) return Data();
auto ncol = Name2ColNum("nphip");
if(ncol == 0) return Data();
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++) out(ix, iy) = (*vylet)[ncol - 1][iy * lons.size() + ix];
out.SetLongName("Number of counterclockwise rotations");
return out;
}
VYLETData::Data VYLETData::ReadPhim() const
{
Data out(lons, lats);
if(!vylet) return Data();
auto ncol = Name2ColNum("nphim");
if(ncol == 0) return Data();
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++) out(ix, iy) = (*vylet)[ncol - 1][iy * lons.size() + ix];
out.SetLongName("Number of clockwise rotations");
return out;
}
VYLETData::Data VYLETData::ReadPhit() const
{
Data out(lons, lats);
if(!vylet) return Data();
auto pcol = Name2ColNum("nphip");
auto mcol = Name2ColNum("nphim");
if(pcol == 0 || mcol == 0) return Data();
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++) out(ix, iy) = (*vylet)[pcol - 1][iy * lons.size() + ix] - (*vylet)[mcol - 1][iy * lons.size() + ix];
out.SetLongName("Difference between the number of rotations counterclockwise and clockwise");
return out;
}
VYLETData::Data VYLETData::ReaddS() const
{
Data out(lons, lats);
if(!vylet) return Data();
auto l1col = Name2ColNum("Log(G.sigma1)");
auto l2col = Name2ColNum("Log(G.sigma2)");
if(l1col == 0 || l2col == 0) return Data();
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++) out(ix, iy) = (*vylet)[l1col - 1][iy * lons.size() + ix] + (*vylet)[l2col - 1][iy * lons.size() + ix];
out.SetLongName("Logarithm of area change multiplier");
return out;
}
VYLETData::Data VYLETData::ReadAngle() const
{
Data out(lons, lats);
if(!vylet) return Data();
auto ncol = Name2ColNum("angle");
if(ncol == 0) return Data();
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++) out(ix, iy) = (*vylet)[ncol - 1][iy * lons.size() + ix] / (2.0 * M_PI);
out.SetLongName("Total rotation angle normalized to 2π");
return out;
}
VYLETData::Data VYLETData::ReadLen() const
{
Data out(lons, lats);
if(!vylet) return Data();
auto ncol = Name2ColNum("length");
if(ncol == 0) return Data();
bool sisangle = !LengthFast();
real mul = sisangle ? (6371.0 * M_PI / (60.0 * 180.0)) : 1.0;
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++) out(ix, iy) = mul * (*vylet)[ncol - 1][iy * lons.size() + ix];
if(sisangle)
{
out.SetUnit("km");
out.SetLongName("Trajectory length");
}
out.SetLongName("Trajectory length (in abstract units)");
return out;
}
VYLETData::Data VYLETData::ReadTmask() const
{
Data out(lons, lats);
if(!vylet) return Data();
auto tcol = Name2ColNum("time");
if(tcol == 0) return Data();
vylet->UsePrefix("");
const real acc = vylet->ParameterRValue("accuracy", 1.0);
const real tstep = 2.0 * M_PI * 1000.0 / acc;
const real maxdays = (end - start).D();
MDateTime time;
real days;
bool maxtime;
for(size_t iy = 0; iy < lats.size(); iy++)
for(size_t ix = 0; ix < lons.size(); ix++)
{
time = R2Time((*vylet)[tcol - 1][iy * lons.size() + ix]);
days = (time - start).D();
maxtime = days >= maxdays - tstep * 0.5;
out(ix, iy) = maxtime ? 1.0 : NAN;
}
out.SetLongName("Flag");
out.SetComment("Values: 1.0 - the trajectory did not reach either the coast or the borders, NaN - overwise");
return out;
}

145
sources/VYLET.h

@ -1,145 +0,0 @@
#pragma once
#include "BFileR.h"
#include "ParseArgs.h"
#include "mdatetime.h"
#include "mregex.h"
#include "simple2ddata.h"
#include <memory>
#include <set>
using michlib::M_PI;
using michlib::MDateTime;
using michlib::real;
using michlib::Round;
class VYLETData
{
std::unique_ptr<michlib::BFileR> vylet;
MDateTime start, end, ref;
bool invtime;
real maxx, maxy;
std::vector<real> lons, lats;
std::vector<real> elon, elat;
MDateTime R2Time(real r) const
{
auto sec = static_cast<time_t>(Round(r * MDateTime::secondsperday));
return ref + (invtime ? -sec : sec);
};
public:
using Data = Rect2DData;
private:
auto Name2ColNum(const MString& name) const
{
auto nc = vylet->Columns();
decltype(nc) i;
for(i = 1; i <= nc; i++)
if(vylet->ColumnName(i) == name) return i;
i = 0;
return i;
}
Data ReadD() const;
Data ReadL() const;
Data ReadT() const;
Data ReadNx() const;
Data ReadNy() const;
Data ReadRx() const;
Data ReadRy() const;
Data ReadEx() const;
Data ReadEy() const;
Data ReadPhip() const;
Data ReadPhim() const;
Data ReadPhit() const;
Data ReaddS() const;
Data ReadAngle() const;
Data ReadLen() const;
Data ReadTmask() const;
public:
static constexpr const char* name = "VYLET";
static constexpr const char* disabledactions = "genintfile uv";
MString DefaultVars() const
{
MString vars = "vylD,vylRx,vylRy,vylEx,vylEy,vylAngle,vylLen";
if(HasLyap()) vars += ",vylL";
if(HasTime()) vars += ",vylT";
return vars;
}
VarPresence CheckVar(const MString& vname) const
{
std::set<MString> vars{"vylD", "vylNx", "vylNy", "vylRx", "vylRy", "vylEx", "vylEy", "vylPhip", "vylPhim", "vylPhit", "vylAngle", "vylLen"};
if(HasLyap()) vars.insert("vylL");
if(HasLyap()) vars.insert("vyldS");
if(HasTime()) vars.insert("vylT");
if(HasTime()) vars.insert("vylTmask");
return vars.contains(vname) ? VarPresence::DERIVED : VarPresence::NONE;
}
bool Read(const MString& vname, std::map<MString, Data>& cache, size_t tind) const;
size_t NTimes() const { return vylet ? 1 : 0; }
MDateTime Time(size_t i) const
{
if(i == 0 && vylet) return start;
return MDateTime();
}
bool HasLyap() const
{
if(!vylet) return false;
vylet->UsePrefix("");
MString method = vylet->ParameterSValue("Method", "");
return method == "BicubicL" || method == "BicubicIL";
}
bool HasCoast() const
{
if(!vylet) return false;
vylet->UsePrefix("");
return vylet->ParameterBValue("checkcoast", true);
}
real Left() const
{
vylet->UsePrefix("");
return vylet->ParameterRValue("xl", -1.0);
}
real Right() const
{
vylet->UsePrefix("");
return vylet->ParameterRValue("xr", maxx + 1.0);
}
real Down() const
{
vylet->UsePrefix("");
return vylet->ParameterRValue("yd", -1.0);
}
real Up() const
{
vylet->UsePrefix("");
return vylet->ParameterRValue("yu", maxy + 1.0);
}
bool HasBorders() const { return Left() >= 0.0 || Right() <= maxx || Down() >= 0.0 || Up() <= maxy; }
bool HasTime() const { return HasCoast() || HasBorders(); }
bool LengthFast() const
{
vylet->UsePrefix("");
return !vylet->ParameterBValue("sisangle", false);
}
MString Info() const;
MString Open(const CLArgs& args);
};

13
src/CMakeLists.txt

@ -2,26 +2,15 @@ set(EXENAME odm)
set(ACTIONLISTINC ${CMAKE_CURRENT_BINARY_DIR}/../include/actionlist.h) # Include actions files and define the actions classes list
set(DATALISTINC ${CMAKE_CURRENT_BINARY_DIR}/../include/datalist.h) # Include data sources files and define the data sources classes list
find_package(PkgConfig REQUIRED)
find_library(netcdf netcdf REQUIRED)
find_library(udunits udunits2 REQUIRED)
find_package(OpenMP REQUIRED)
find_package(CURL REQUIRED)
find_package(LibXml2 REQUIRED)
find_package(SQLite3 REQUIRED)
pkg_check_modules(JSONCPP REQUIRED jsoncpp)
pkg_check_modules(BLOSC REQUIRED blosc)
pkg_check_modules(LIBPQ REQUIRED libpq)
set (CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} ${OpenMP_CXX_FLAGS}")
include_directories(${JSONCPP_INCLUDE_DIRS} ${BLOSC_INCLUDE_DIRS} ${LIBPQ_INCLUDE_DIRS} ${LIBXML2_INCLUDE_DIRS} ${SQLite3_INCLUDE_DIRS})
file(GLOB srcs CONFIGURE_DEPENDS *.cpp)
add_executable(${EXENAME} ${srcs} ${ACTIONLISTINC} ${SOURCELISTINC})
target_include_directories(${EXENAME} PRIVATE ../michlib/michlib ${CMAKE_CURRENT_BINARY_DIR}/../include)
target_link_libraries(${EXENAME} ${linker_options} ${netcdf} ${udunits} OpenMP::OpenMP_CXX CURL::libcurl ${JSONCPP_LINK_LIBRARIES} ${BLOSC_LINK_LIBRARIES} ${LIBPQ_LINK_LIBRARIES} LibXml2::LibXml2 SQLite::SQLite3 teos)
target_link_libraries(${EXENAME} ${linker_options} ${netcdf} OpenMP::OpenMP_CXX teos)
set_target_properties(${EXENAME} PROPERTIES POSITION_INDEPENDENT_CODE ON)
install(TARGETS ${EXENAME})

254
src/cache.cpp

@ -1,254 +0,0 @@
#define MICHLIB_NOSOURCE
#include "cache.h"
SQLiteConnection::DBType SQLiteConnection::db = nullptr;
size_t SQLiteConnection::count = 0;
std::vector<SQLiteConnection::FuncType> SQLiteConnection::destructs = {};
PostgreSQLConnection::DBType PostgreSQLConnection::conn = nullptr;
size_t PostgreSQLConnection::count = 0;
std::vector<PostgreSQLConnection::FuncType> PostgreSQLConnection::destructs = {};
bool SQLiteCache::regdest = false;
bool PostgreSQLCache::regdest = false;
bool FileInfoCache::regdest = false;
void FileInfoCache::GetDirId()
{
if(dirid != 0) return;
const char* params[] = {dir.Buf()};
int plens[] = {int_cast<int>(dir.Len())};
int pfor[] = {0};
PGresultRAII res = PQexecParams(conn, "SELECT id FROM dirs WHERE name=$1::text;", 1, nullptr, params, plens, pfor, 1);
if(PQresultStatus(res) != PGRES_TUPLES_OK)
{
michlib::errmessage(PQresStatus(PQresultStatus(res)));
michlib::errmessage(PQerrorMessage(conn));
return;
}
else if(PQntuples(res) == 0)
{
res = PQexecParams(conn,
"INSERT INTO dirs(name,id) VALUES ($1, (SELECT min(num.numid) FROM (SELECT generate_series(1, (SELECT COALESCE((SELECT max(id) FROM dirs), 1)) + "
"1, 1) AS numid) num LEFT JOIN dirs ON dirs.id=num.numid WHERE id IS NULL)) RETURNING id;",
1, nullptr, params, plens, pfor, 1);
if(PQresultStatus(res) != PGRES_COMMAND_OK && PQresultStatus(res) != PGRES_TUPLES_OK)
{
michlib::errmessage(PQresStatus(PQresultStatus(res)));
michlib::errmessage(PQerrorMessage(conn));
}
if(PQntuples(res) == 0) return;
}
if(PQgetlength(res, 0, 0) == sizeof(dirid)) dirid = *pointer_cast<const decltype(dirid)*>(PQgetvalue(res, 0, 0));
michlib::message("Dirid: ", Invert(dirid));
}
FileInfoCache::FileInfoCache(FileInfoCache::CallbackType&& readfunc_, const MString& dir_): readfunc(std::move(readfunc_)), dir(dir_), dirid(0)
{
if(!conn) return;
if(!regdest)
{
// Create table
PGresultRAII res = PQexec(conn, "SET client_min_messages=WARNING;");
res = PQexec(conn, "BEGIN;"
"CREATE TABLE IF NOT EXISTS dirs(name TEXT PRIMARY KEY, id INTEGER UNIQUE NOT NULL CONSTRAINT id_is_positive CHECK(id>0));"
"CREATE TABLE IF NOT EXISTS files(name TEXT NOT NULL, size BIGINT NOT NULL CONSTRAINT size_is_positive CHECK(size>0), modtime TIMESTAMP(0) NOT NULL, "
"dirid INTEGER REFERENCES dirs(id) ON DELETE CASCADE, lastaccess TIMESTAMP(0) NOT NULL, data BYTEA NOT NULL, PRIMARY KEY(name,dirid));"
"COMMIT;");
if(PQresultStatus(res) != PGRES_COMMAND_OK)
{
michlib::errmessage(PQresStatus(PQresultStatus(res)));
michlib::errmessage(PQerrorMessage(conn));
}
res = PQexec(conn, "SET client_min_messages=NOTICE;");
conn.AddDestructor(
[](PostgreSQLConnection::DBType conn)
{
PGresultRAII res = PQexec(conn, "BEGIN;"
"DELETE FROM files WHERE lastaccess+'100 days'::interval<localtimestamp;"
"DELETE FROM dirs WHERE id NOT IN (SELECT dirid FROM files);"
"COMMIT;");
});
regdest = true;
}
GetDirId();
//UpdateCache();
}
Error FileInfoCache::UpdateCache(bool force) const
{
const static MString pref = "FileInfoCache::UpdateCache";
DIRRAII dhandle;
dhandle.reset(opendir(dir.Buf()));
if(!dhandle) return {pref, "Can't open directory " + dir};
int dfd = dirfd(dhandle);
errno = 0;
struct dirent* dent = readdir(dhandle);
if(errno != 0) return {pref, "Can't read directory " + dir};
struct stat st;
do {
if(dent->d_name[0] != '.')
{
int ret = fstatat(dfd, dent->d_name, &st, 0);
if(ret != 0) return {pref, "Can't stat " + dir + "/" + dent->d_name};
if(S_ISREG(st.st_mode)) // Regular file
{
const char* params[] = {dent->d_name, pointer_cast<const char*>(&dirid)};
int plens[] = {int_cast<int>(strlen(dent->d_name)), sizeof(dirid)};
int pfor[] = {0, 1};
bool querysucc = true;
time_t modtime;
size_t size;
PGresultRAII res = PQexecParams(conn, "SELECT size,modtime FROM files WHERE name=$1::text AND dirid=$2::integer;", 2, nullptr, params, plens, pfor, 1);
if(PQresultStatus(res) != PGRES_COMMAND_OK && PQresultStatus(res) != PGRES_TUPLES_OK)
{
michlib::errmessage(PQresStatus(PQresultStatus(res)));
michlib::errmessage(PQerrorMessage(conn));
querysucc = false;
}
else if(PQntuples(res) == 0 || PQntuples(res) > 1)
querysucc = false;
if(querysucc)
{
size = *pointer_cast<const decltype(size)*>(PQgetvalue(res, 0, 0));
modtime = raw2epoch(*pointer_cast<const time_t*>(PQgetvalue(res, 0, 1)));
}
else
{
size = int_cast<size_t>(st.st_size);
modtime = st.st_mtim.tv_sec;
}
if(!querysucc || force || size != int_cast<size_t>(st.st_size) || modtime != st.st_mtim.tv_sec)
{
auto ret = GetData(dent->d_name);
// Remove entry
if(!ret && querysucc)
{
PGresultRAII dres = PQexecParams(conn, "DELETE FROM files WHERE name=$1::text AND dirid=$2::integer;", 2, nullptr, params, plens, pfor, 1);
if(PQresultStatus(dres) != PGRES_COMMAND_OK)
{
michlib::errmessage(PQresStatus(PQresultStatus(dres)));
michlib::errmessage(PQerrorMessage(conn));
}
}
else // Update or insert
{
auto sizei = Invert(size);
auto modtimei = epoch2raw(modtime);
const char* params[] = {dent->d_name, pointer_cast<const char*>(&sizei), pointer_cast<const char*>(&modtimei), pointer_cast<const char*>(&dirid), ret.value().Buf()};
int plens[] = {int_cast<int>(strlen(dent->d_name)), sizeof(sizei), sizeof(modtimei), sizeof(dirid), int_cast<int>(ret.value().Len())};
int pfor[] = {0, 1, 1, 1, 1};
PGresultRAII res = PQexecParams(conn,
"INSERT INTO files (name,size,modtime,dirid,lastaccess,data) VALUES($1::text, $2::bigint, $3::timestamp, $4::integer, localtimestamp, $5) "
"ON CONFLICT ON CONSTRAINT files_pkey DO UPDATE SET "
"size=EXCLUDED.size, modtime=EXCLUDED.modtime, lastaccess=EXCLUDED.lastaccess, data=EXCLUDED.data;",
5, nullptr, params, plens, pfor, 1);
if(PQresultStatus(res) != PGRES_COMMAND_OK)
{
michlib::errmessage(PQresStatus(PQresultStatus(res)));
michlib::errmessage(PQerrorMessage(conn));
}
} // Insert or update branch
} // Need data update
} // Regular file
} // if(dent->d_name[0] != '.')
dent = readdir(dhandle);
} while(dent != nullptr || errno != 0);
return Error();
}
FileInfoCache::DataType FileInfoCache::GetInfo(const MString& name) const
{
if(!*this) return GetData(name);
bool querysucc = true;
MString data;
time_t modtime;
size_t size;
{
const char* params[] = {name.Buf(), pointer_cast<const char*>(&dirid)};
int plens[] = {int_cast<int>(name.Len()), sizeof(dirid)};
int pfor[] = {0, 1};
PGresultRAII res =
PQexecParams(conn, "UPDATE files SET lastaccess=localtimestamp WHERE name=$1::text AND dirid=$2::integer RETURNING data,size,modtime;", 2, nullptr, params, plens, pfor, 1);
if(PQresultStatus(res) != PGRES_COMMAND_OK && PQresultStatus(res) != PGRES_TUPLES_OK)
{
michlib::errmessage(PQresStatus(PQresultStatus(res)));
michlib::errmessage(PQerrorMessage(conn));
querysucc = false;
}
if(PQntuples(res) == 0 || PQntuples(res) > 1)
{
michlib::errmessage("Data for file ", dir + "/" + name, (PQntuples(res) == 0 ? " not found " : " duplicated "), "in cache");
querysucc = false;
}
if(querysucc)
{
data = MString(PQgetvalue(res, 0, 0), PQgetlength(res, 0, 0));
size = *pointer_cast<const decltype(size)*>(PQgetvalue(res, 0, 1));
modtime = raw2epoch(*pointer_cast<const time_t*>(PQgetvalue(res, 0, 2)));
}
}
{
struct stat st;
int ret = stat((dir + "/" + name).Buf(), &st);
if(ret != 0) return DataType();
if(querysucc && st.st_mtim.tv_sec == modtime && size == int_cast<size_t>(st.st_size)) return data;
modtime = st.st_mtim.tv_sec;
size = st.st_size;
}
auto ret = GetData(name);
if(ret)
{
auto sizei = Invert(size);
auto modtimei = epoch2raw(modtime);
const char* params[] = {name.Buf(), pointer_cast<const char*>(&sizei), pointer_cast<const char*>(&modtimei), pointer_cast<const char*>(&dirid), ret.value().Buf()};
int plens[] = {int_cast<int>(name.Len()), sizeof(sizei), sizeof(modtimei), sizeof(dirid), int_cast<int>(ret.value().Len())};
int pfor[] = {0, 1, 1, 1, 1};
PGresultRAII res = PQexecParams(conn,
"INSERT INTO files (name,size,modtime,dirid,lastaccess,data) VALUES($1::text, $2::bigint, $3::timestamp, $4::integer, localtimestamp, $5) "
"ON CONFLICT ON CONSTRAINT files_pkey DO UPDATE SET "
"size=EXCLUDED.size, modtime=EXCLUDED.modtime, lastaccess=EXCLUDED.lastaccess, data=EXCLUDED.data;",
5, nullptr, params, plens, pfor, 1);
if(PQresultStatus(res) != PGRES_COMMAND_OK)
{
michlib::errmessage(PQresStatus(PQresultStatus(res)));
michlib::errmessage(PQerrorMessage(conn));
}
}
return ret;
}

180
src/copcat.cpp

@ -1,180 +0,0 @@
#define MICHLIB_NOSOURCE
#include "copcat.h"
#include "GPL.h"
#include "mirrorfuncs.h"
const MString CopernicusCatalog::caturl = "https://stac.marine.copernicus.eu/metadata/catalog.stac.json";
CopernicusCatalog::CopernicusCatalog()
{
auto oldprefix = michlib::GPL.UsePrefix("COPERNICUS");
// Cache
cache.reset(CreateCache(michlib::GPL.ParameterSValue("Cache", "")));
if(!cache)
{
michlib::errmessage("Can't init cache");
cache.reset(new FakeCache);
}
// Proxy
auto proxyurl = michlib::GPL.ParameterSValue("Proxy", "");
if(proxyurl.Exist()) curl_easy_setopt(chandle, CURLOPT_PROXY, proxyurl.Buf());
michlib::GPL.UsePrefix(oldprefix);
GetCatalog();
}
Error CopernicusCatalog::GetCatalog()
{
if(Valid()) return Error();
auto ret = GetJSON(caturl);
if(ret)
catalog = ret.Value();
else
return ret.Add("CopernicusCatalog::GetCatalog", "can't download catalog");
return Error();
}
RetVal<std::vector<MString>> CopernicusCatalog::ProductList() const
{
static const MString pref = "CopernicusCatalog::ProductList";
if(!Valid()) return {pref, "no catalog"};
const auto& links = catalog["links"];
if(links.type() != Json::arrayValue) return {pref, "no \"links\" section in the catalog"};
std::vector<MString> out;
for(Json::ArrayIndex i = 0; i < links.size(); i++)
{
const auto& rel = links[i]["rel"];
const auto& href = links[i]["href"];
if(rel.type() == Json::stringValue && href.type() == Json::stringValue && rel.asString() == "child")
{
auto str = href.asString();
str.erase(str.find('/'));
out.emplace_back(str.c_str());
}
}
return out;
}
RetVal<MString> CopernicusCatalog::ProductURL(const MString& prod) const
{
static const MString pref = "CopernicusCatalog::ProductURL";
if(!Valid()) return {pref, "no catalog"};
const auto& links = catalog["links"];
if(links.type() != Json::arrayValue) return {pref, "no \"links\" section in the catalog"};
for(Json::ArrayIndex i = 0; i < links.size(); i++)
{
const auto& href = links[i]["href"];
if(href.type() == Json::stringValue && href.asString() == (prod + "/product.stac.json").Buf()) return DirName(caturl) + "/" + MString(href.asString().c_str());
}
return {pref, "unknown product: " + prod};
}
RetVal<std::vector<MString>> CopernicusCatalog::DatasetList(const MString& prod) const
{
static const MString pref = "CopernicusCatalog::DatasetList";
MString url;
{
auto ret = ProductURL(prod);
if(!ret) return ret.Add(pref, "Can't get url for the product " + prod);
url = ret.Value();
}
auto ret = GetJSON(url);
if(!ret) return ret.Add(pref, "Can't download product " + prod);
const auto& links = ret.Value()["links"];
if(links.type() != Json::arrayValue) return {pref, "no \"links\" section in the product " + prod + " description"};
std::vector<MString> out;
for(Json::ArrayIndex i = 0; i < links.size(); i++)
{
const auto& rel = links[i]["rel"];
const auto& href = links[i]["href"];
if(rel.type() == Json::stringValue && href.type() == Json::stringValue && rel.asString() == "item")
{
auto str = href.asString();
str.erase(str.find('/'));
out.emplace_back(str.c_str());
}
}
return out;
}
RetVal<MString> CopernicusCatalog::DatasetURL(const MString& prod, const MString& dataset) const
{
static const MString pref = "CopernicusCatalog::DatasetURL";
MString url;
{
auto ret = ProductURL(prod);
if(!ret) return ret.Add(pref, "Can't get url for the product " + prod);
url = ret.Value();
}
auto ret = GetJSON(url);
if(!ret) return ret.Add(pref, "Can't download product " + prod);
const auto& links = ret.Value()["links"];
if(links.type() != Json::arrayValue) return {pref, "no \"links\" section in the product " + prod + " description"};
for(Json::ArrayIndex i = 0; i < links.size(); i++)
{
const auto& href = links[i]["href"];
if(href.type() == Json::stringValue && href.asString() == (dataset + "/dataset.stac.json").Buf()) return DirName(url) + "/" + MString(href.asString().c_str());
}
return {pref, "unknown dataset: " + dataset};
}
RetVal<MString> CopernicusCatalog::AssetURL(const MString& prod, const MString& dataset, const MString& asset) const
{
static const MString pref = "CopernicusCatalog::AssetURL";
MString url;
{
auto ret = DatasetURL(prod, dataset);
if(!ret) return ret.Add(pref, "Can't get url for the dataset " + dataset);
url = ret.Value();
}
auto ret = GetJSON(url);
if(!ret) return ret.Add(pref, "Can't download dataset " + dataset);
const auto& href = ret.Value()["assets"][asset.Buf()]["href"];
if(!href || href.type() != Json::stringValue) return {pref, "href for the asset " + asset + " not found"};
return MString(href.asString().c_str());
}
RetVal<Json::Value> CopernicusCatalog::GetJSON(const MString& url) const
{
const static MString pref = "CopernicusCatalog::GetJSON";
Json::Reader reader;
Json::Value obj;
MString content;
auto [val, suc] = cache->Get(url);
if(suc)
content = std::move(val);
else
{
michlib::message(url + " not found in cache, downloading");
auto [out, res] = GetUrl(chandle, url);
if(res != CURLE_OK) return Error(pref, MString("can't download JSON: ") + chandle.Err());
cache->Put(url, out, 3600);
content = std::move(out);
}
reader.parse(content.Buf(), content.Buf() + content.Len(), obj, false);
return obj;
}

41
src/curlfuncs.cpp

@ -1,41 +0,0 @@
#define MICHLIB_NOSOURCE
#include "curlfuncs.h"
#include <unistd.h>
using michlib::pointer_cast;
using michlib::uint1;
size_t Write2String(char* ptr, size_t size, size_t n, void* data)
{
MString* out = pointer_cast<MString*>(data);
*out += MString(ptr, size * n);
return size * n;
}
size_t Write2File(char* ptr, size_t size, size_t n, void* data)
{
const int* fd = pointer_cast<const int*>(data);
size_t count = size * n;
const uint1* buf = pointer_cast<const uint1*>(ptr);
while(count != 0)
{
auto wr = write(*fd, buf, count);
if(wr == -1) return 0;
count -= wr;
buf += wr;
}
return size * n;
}
std::pair<MString, CURLcode> GetUrl(const CURLRAII& chandle, const MString& url)
{
MString out;
curl_easy_setopt(chandle, CURLOPT_URL, url.Buf());
curl_easy_setopt(chandle, CURLOPT_WRITEFUNCTION, Write2String);
curl_easy_setopt(chandle, CURLOPT_WRITEDATA, &out);
auto res = curl_easy_perform(chandle);
return {out, res};
}

102
src/layereddata.cpp

@ -51,9 +51,8 @@ MString LayeredData::Open(const MString& dataset)
nc.emplace_back(std::move(url));
if(!nc.back())
{
auto failedurl = nc.back().Url();
nc.clear();
return "Can't connect to url " + failedurl;
return "Can't connect to url " + url;
}
}
else
@ -140,31 +139,21 @@ std::pair<const BaseParameters*, MString> LayeredData::Parameters(michlib_intern
real lon2 = ToGeoDomain(reg.lone, dom);
real lat1 = reg.latb;
real lat2 = reg.late;
bool global = lone - lonb + 1.5 * lonstep > 360.0;
// Special case when the longitude lies in a small sector between the end and the start
if(global)
{
if(lon1 < lonb) lon1 = lone;
if(lon2 > lone) lon2 = lonb;
}
else
{
if(lon1 < lonb) lon1 = lonb;
if(lon2 > lone) lon2 = lone;
}
ppar->xb = static_cast<size_t>(Floor((lon1 - lonb) / lonstep));
ppar->xe = static_cast<size_t>(Ceil((lon2 - lonb) / lonstep));
if(ppar->xb == ppar->xe) return {nullptr, "Lonb must be not equal late"};
if(!global && ppar->xb > ppar->xe) return {nullptr, "Lonb must be lesser then lone"};
ppar->yb = static_cast<size_t>(Floor((lat1 - latb) / latstep));
ppar->ye = static_cast<size_t>(Ceil((lat2 - latb) / latstep));
if(ppar->ye > dname.ny - 1) ppar->ye = dname.ny - 1;
if(ppar->yb >= ppar->ye) return {nullptr, "Latb must be lesser then late"};
ppar->xb = static_cast<size_t>(Floor((lon1 - lonb) / lonstep));
ppar->xe = static_cast<size_t>(Ceil((lon2 - lonb) / lonstep));
if(ppar->xb == ppar->xe) return {nullptr, "Lonb must be not equal late"};
if(depth < 0.0 || depth > depths.back())
ppar->layer = (depth < 0.0) ? 0 : (depths.size() - 1);
else
@ -197,7 +186,84 @@ bool LayeredData::Read(const MString& vname, std::map<MString, LayeredData::Data
auto p = dynamic_cast<const struct Parameters*>(ip);
auto [name, id, tid] = VarNameLoc(vname, times[i]);
if(!name.Exist()) // Conversion read
return TransformationRead(this, vname, cache, ip, i);
{
// ptemp from temp and sal
if(vname == "ptemp")
{
if(!(Read("temp", cache, ip, i) && Read("sal", cache, ip, i))) return false;
cache[vname] = cache.at("temp").CopyGrid();
auto& ptemp = cache.at(vname);
const auto& temp = cache.at("temp");
const auto& sal = cache.at("sal");
ptemp.SetUnit("degrees_C");
for(size_t ind = 0; ind < ptemp.N(); ind++)
{
if(temp.IsFill(ind) || sal.IsFill(ind))
ptemp.V(ind) = ptemp.Fillval();
else
ptemp.V(ind) = Temp2PTemp(temp.V(ind), sal.V(ind), Depth(p->layer), ptemp.Lon(ind), ptemp.Lat(ind));
}
return true;
}
// temp from ptemp and sal
if(vname == "temp")
{
if(!(Read("ptemp", cache, ip, i) && Read("sal", cache, ip, i))) return false;
cache[vname] = cache.at("ptemp").CopyGrid();
auto& temp = cache.at(vname);
const auto& ptemp = cache.at("ptemp");
const auto& sal = cache.at("sal");
temp.SetUnit("degrees_C");
for(size_t ind = 0; ind < temp.N(); ind++)
{
if(ptemp.IsFill(ind) || sal.IsFill(ind))
temp.V(ind) = temp.Fillval();
else
temp.V(ind) = PTemp2Temp(ptemp.V(ind), sal.V(ind), Depth(p->layer), temp.Lon(ind), temp.Lat(ind));
}
return true;
}
// pdens from temp and sal
if(vname == "pdens")
{
bool tempispot = HaveVar("ptemp");
if(!(Read(tempispot ? "ptemp" : "temp", cache, ip, i) && Read("sal", cache, ip, i))) return false;
cache[vname] = cache.at("sal").CopyGrid();
auto& pdens = cache.at(vname);
const auto& temp = cache.at(tempispot ? "ptemp" : "temp");
const auto& sal = cache.at("sal");
pdens.SetUnit("kg m-3");
for(size_t ind = 0; ind < pdens.N(); ind++)
{
if(temp.IsFill(ind) || sal.IsFill(ind))
pdens.V(ind) = pdens.Fillval();
else
pdens.V(ind) = tempispot ? PTemp2PDens(temp.V(ind), sal.V(ind), Depth(p->layer), pdens.Lon(ind), pdens.Lat(ind))
: Temp2PDens(temp.V(ind), sal.V(ind), Depth(p->layer), pdens.Lon(ind), pdens.Lat(ind));
}
return true;
}
// U and U2 from u and v
if(vname == "U" || vname == "U2")
{
bool square = vname == "U2";
if(!(Read("u", cache, ip, i) && Read("v", cache, ip, i))) return false;
cache[vname] = cache.at("u").CopyGrid();
auto& U = cache.at(vname);
const auto& u = cache.at("u");
const auto& v = cache.at("v");
if(u.Unit().Exist()) U.SetUnit(square ? ("(" + u.Unit() + ")2") : u.Unit());
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 true;
}
return false;
}
// Direct read
bool nodepth = false;

295
src/layereddataz.cpp

@ -1,295 +0,0 @@
#define MICHLIB_NOSOURCE
#include "layereddataz.h"
MString LayeredDataZ::Info() const
{
if(!isOk()) return "";
MString d;
for(size_t i = 0; i < NDepths(); i++) d += MString(" ") + "(" + i + " " + Depth(i) + ")";
std::set<MString> vars;
for(const auto& f: nc) GetVars(f, vars);
MString svars;
{
bool first = true;
for(const auto& v: vars)
{
svars += (first ? "" : ", ") + v;
first = false;
}
}
// clang-format off
return
"Dataset: " + Title() + "\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: " + dname.nx + "x" + dname.ny + " (" + lonstep + " x " + latstep + ")\n" +
" Depths:" + d + "\n" +
" Supported variables: " + svars;
// clang-format on
}
MString LayeredDataZ::Open(const MString& dataset)
{
nc.clear();
MString proxyurl = GPL.ParameterSValue("USEPROXY", "");
if(proxyurl.Exist()) proxy.Activate("all_proxy", proxyurl);
nc.clear();
size_t i = 1;
while(true)
{
MString url = GPL.ParameterSValue(dataset + "_URL" + i, "");
if(url.Exist())
{
// Split url on product and dataset
auto words = url.Split(":");
if(words.size() == 0 || words.size() > 2)
{
nc.clear();
return "Invalid url " + url;
}
MString product = words[0];
MString dataset = words.size() == 2 ? words[1] : "";
nc.emplace_back();
{
auto ret = nc.back().OpenZarr(product, dataset);
if(!ret)
{
nc.clear();
return "Can't open " + dataset + " of " + product;
}
}
}
else
break;
i++;
}
if(nc.size() == 0) return "No urls for dataset " + dataset + " specified in config";
dname = GetDNames(nc[0]);
if(!(dname.lonname.Exist() && dname.latname.Exist()))
{
nc.clear();
return "Can't find longitude/latitude";
}
if(!dname.timename.Exist())
{
nc.clear();
return "Can't find time";
}
auto cn = GetCNames(nc[0]);
// Read times
for(auto& f: nc)
{
auto ret = f.ReadTimes(cn.timename);
if(!ret)
{
nc.clear();
return "Can't read times";
}
times.insert(times.end(), f.Times().begin(), f.Times().end());
}
std::sort(times.begin(), times.end());
auto last = std::unique(times.begin(), times.end());
times.erase(last, times.end());
depthinv = false;
if(cn.depthname.Exist())
{
auto ret = nc[0].Read(cn.depthname, depths);
if(!ret)
{
nc.clear();
return "Can't read depths";
}
if(depths.back() <= 0 && depths.front() <= 0) std::ranges::transform(depths, depths.begin(), std::negate{});
if(depths.back() < depths.front() && depths.size() > 1)
{
depthinv = true;
for(size_t i = 0; i < depths.size() - i - 1; i++) std::swap(depths[i], depths[depths.size() - i - 1]);
}
}
else // Surface only data
{
depths.resize(1);
depths[0] = 0;
}
std::vector<double> lons, lats;
{
auto ret = nc[0].Read(cn.lonname, lons);
if(!ret)
{
nc.clear();
return "Can't get longitudes";
}
}
{
auto ret = nc[0].Read(cn.latname, lats);
if(!ret)
{
nc.clear();
return "Can't get latitudes";
}
}
lonb = lons[0];
latb = lats[0];
lone = lons.back();
late = lats.back();
lonstep = (lone - lonb) / (dname.nx - 1);
latstep = (late - latb) / (dname.ny - 1);
return "";
}
std::pair<const BaseParameters*, MString> LayeredDataZ::Parameters(michlib_internal::ParameterListEx& pars, const CLArgs& args, const struct Region& reg) const
{
std::unique_ptr<struct Parameters> ppar{new struct Parameters};
ppar->layer = args.contains("layer") ? args.at("layer").ToInteger<size_t>() : 0;
if(!args.contains("depth") && ppar->layer >= NDepths()) return {nullptr, MString("Layer ") + ppar->layer + " is too deep!"};
real depth = args.contains("depth") ? args.at("depth").ToReal() : Depth(ppar->layer);
{
auto dom = DetGeoDomain(lonb, lone);
real lon1 = ToGeoDomain(reg.lonb, dom);
real lon2 = ToGeoDomain(reg.lone, dom);
real lat1 = reg.latb;
real lat2 = reg.late;
bool global = lone - lonb + 1.5 * lonstep > 360.0;
// Special case when the longitude lies in a small sector between the end and the start
if(global)
{
if(lon1 < lonb) lon1 = lone;
if(lon2 > lone) lon2 = lonb;
}
else
{
if(lon1 < lonb) lon1 = lonb;
if(lon2 > lone) lon2 = lone;
}
ppar->xb = static_cast<size_t>(Floor((lon1 - lonb) / lonstep));
ppar->xe = static_cast<size_t>(Ceil((lon2 - lonb) / lonstep));
if(ppar->xb == ppar->xe) return {nullptr, "Lonb must be not equal late"};
if(!global && ppar->xb > ppar->xe) return {nullptr, "Lonb must be lesser then lone"};
ppar->yb = static_cast<size_t>(Floor((lat1 - latb) / latstep));
ppar->ye = static_cast<size_t>(Ceil((lat2 - latb) / latstep));
if(ppar->ye > dname.ny - 1) ppar->ye = dname.ny - 1;
if(ppar->yb >= ppar->ye) return {nullptr, "Latb must be lesser then late"};
if(depth < 0.0 || depth > depths.back())
ppar->layer = (depth < 0.0) ? 0 : (depths.size() - 1);
else
for(size_t i = 0; i < depths.size() - 1; i++)
{
if(depth >= depths[i] && depth <= depths[i + 1])
{
ppar->layer = (depth - depths[i] <= depths[i + 1] - depth) ? i : (i + 1);
break;
}
}
}
pars.SetParameter("depth", Depth(ppar->layer));
pars.SetParameter("layer", ppar->layer);
pars.SetParameter("dataset", Title());
pars.SetParameter("lonb", Lon(ppar->xb));
pars.SetParameter("latb", Lat(ppar->yb));
pars.SetParameter("lone", Lon(ppar->xe));
pars.SetParameter("late", Lat(ppar->ye));
return {ppar.release(), ""};
}
bool LayeredDataZ::Read(const MString& vname, std::map<MString, LayeredDataZ::Data>& cache, const BaseParameters* ip, size_t i) const
{
if(cache.contains(vname)) return true;
if(!isOk()) return false;
auto p = dynamic_cast<const struct Parameters*>(ip);
auto [name, id, tid] = VarNameLoc(vname, times[i]);
if(!name.Exist()) // Conversion read
return TransformationRead(this, vname, cache, ip, i);
// Direct read
bool nodepth = false;
Data data;
//auto head = nc[id]->Header();
for(const auto& v: nc[id].VarNames())
if(v == name)
{
if(nc[id].NDim(v) == 3) nodepth = true;
data = ReadVarRaw(nc[id], name, tid, nodepth, p);
if(data)
{
cache[vname] = std::move(data);
return true;
}
}
return false;
}
LayeredDataZ::Data LayeredDataZ::ReadVarRaw(const NC& f, const MString& name, size_t i, bool nodepth, const struct LayeredDataZ::Parameters* p) const
{
real unitmul = 1.0;
real offset = 0.0, scale = 1.0;
if(f.HasAtt(name, "add_offset")) offset = f.AttReal(name, "add_offset");
if(f.HasAtt(name, "scale_factor")) scale = f.AttReal(name, "scale_factor");
MString unit;
if(f.HasAtt(name, "units")) unit = f.AttString(name, "units");
if(unit == "m s-1" || unit == "m/s")
{
unitmul = 100.0;
unit = "cm/s";
}
Data data((p->xb < p->xe) ? (p->xe - p->xb + 1) : (dname.nx + p->xe - p->xb + 1), p->ye - p->yb + 1, Lon(p->xb), Lat(p->yb), lonstep, latstep, std::move(unit));
auto trans = [scale, offset, unitmul](auto raw) -> real { return (raw * scale + offset) * unitmul; };
auto rlayer = depthinv ? depths.size() - p->layer - 1 : p->layer;
if(p->xb < p->xe)
{
auto ret = nodepth ? f.Read(name, data, trans, {dname.lonname, p->xb, p->xe - p->xb + 1}, {dname.latname, p->yb, p->ye - p->yb + 1}, {dname.timename, i, 1})
: f.Read(name, data, trans, {dname.lonname, p->xb, p->xe - p->xb + 1}, {dname.latname, p->yb, p->ye - p->yb + 1}, {dname.timename, i, 1},
{dname.depthname, rlayer, 1});
if(!ret) return Data();
}
else
{
{
auto ret = nodepth ? f.Read(name, data, trans, {dname.lonname, p->xb, dname.nx - p->xb}, {dname.latname, p->yb, p->ye - p->yb + 1}, {dname.timename, i, 1})
: f.Read(name, data, trans, {dname.lonname, p->xb, dname.nx - p->xb}, {dname.latname, p->yb, p->ye - p->yb + 1}, {dname.timename, i, 1},
{dname.depthname, rlayer, 1});
if(!ret) return Data();
}
{
size_t shift = dname.nx - p->xb + 1;
auto shifteddata = [&data, shift](size_t ix, size_t iy) -> real& { return data(ix + shift, iy); };
auto ret =
nodepth ? f.Read(name, shifteddata, trans, {dname.lonname, 0, p->xe + 1}, {dname.latname, p->yb, p->ye - p->yb + 1}, {dname.timename, i, 1})
: f.Read(name, shifteddata, trans, {dname.lonname, 0, p->xe + 1}, {dname.latname, p->yb, p->ye - p->yb + 1}, {dname.timename, i, 1}, {dname.depthname, rlayer, 1});
if(!ret) return Data();
}
}
return data;
}

134
src/mirrorfuncs.cpp

@ -1,134 +0,0 @@
#define MICHLIB_NOSOURCE
#include "mirrorfuncs.h"
#include "StringFunctions.h"
#include "filehelpers.h"
#include "merrors.h"
using michlib::FD;
using michlib::message;
bool MakePath(const MString& dname)
{
struct stat st;
int ret = stat(dname.Buf(), &st);
if(ret == 0) return S_ISDIR(st.st_mode);
auto dirs = michlib::Split_on_words(dname, "/", false);
MString cdir = "";
for(const auto& dir: dirs)
{
cdir += "/" + dir;
ret = stat(cdir.Buf(), &st);
if(ret == 0 && S_ISDIR(st.st_mode)) continue;
if(ret == 0 && !S_ISDIR(st.st_mode)) return false;
ret = mkdir(cdir.Buf(), 0755);
if(ret != 0) return false;
}
return true;
}
RetVal<std::vector<struct FileInfo>> ReadLocalFileList(const MString& dir, const bool nofollow, const MString& path)
{
const static MString pref = "ReadLocalFileList";
std::vector<struct FileInfo> out;
DIRRAII dhandle;
MakePath(dir);
dhandle.reset(opendir(dir.Buf()));
if(!dhandle) return {pref, "Can't open directory " + path + (path.Exist() ? "/" : "") + dir};
int dfd = dirfd(dhandle);
errno = 0;
struct dirent* dent = readdir(dhandle);
if(errno != 0) return {pref, "Can't read directory " + path + (path.Exist() ? "/" : "") + dir};
struct stat st;
do {
if(dent->d_name[0] != '.')
{
int ret = fstatat(dfd, dent->d_name, &st, nofollow ? AT_SYMLINK_NOFOLLOW : 0);
if(ret != 0) return {pref, "Can't stat " + path + "/" + dir + "/" + dent->d_name};
if(S_ISDIR(st.st_mode)) // Directory, recurse
{
auto list = ReadLocalFileList(dir + "/" + dent->d_name, nofollow, path + (path.Exist() ? "/" : "") + dent->d_name);
if(!list) return list;
out.insert(out.end(), list.Value().begin(), list.Value().end());
}
if(S_ISREG(st.st_mode)) // Regular file
{
out.emplace_back(dir + "/" + dent->d_name, path + (path.Exist() ? "/" : "") + dent->d_name, MDateTime(st.st_mtim.tv_sec, st.st_mtim.tv_nsec), st.st_size);
}
// Ignore non-directories, non-files
}
dent = readdir(dhandle);
} while(dent != nullptr || errno != 0);
if(errno != 0) return {pref, "Can't read directory " + path + "/" + dir};
std::sort(out.begin(), out.end(), [](const struct FileInfo& a, const struct FileInfo& b) { return a.name < b.name; });
return out;
}
Error DownloadFile(const CURLRAII& chandle, const struct FileInfo& rinfo, const MString& root)
{
const static MString pref = "DownloadFile";
message("Downloading " + rinfo.url);
MString dname = DirName(rinfo.name), fname = FileName(rinfo.name);
FD fd;
if(!MakePath(root + "/" + dname)) return {pref, "Can't create directory " + root + "/" + dname};
fd.Reset(creat((root + "/" + rinfo.name).Buf(), 0644));
if(!fd) return {pref, "Can't create file " + root + "/" + rinfo.name};
int cfd = fd.Get();
curl_easy_setopt(chandle, CURLOPT_WRITEFUNCTION, Write2File);
curl_easy_setopt(chandle, CURLOPT_WRITEDATA, &cfd);
curl_easy_setopt(chandle, CURLOPT_URL, rinfo.url.Buf());
auto res = curl_easy_perform(chandle);
if(res != CURLE_OK)
{
unlink((root + "/" + rinfo.name).Buf());
return {pref, MString("Can't download file: ") + chandle.Err()};
}
{
struct timespec times[2];
times[0].tv_sec = times[1].tv_sec = rinfo.mtime.Epoch();
times[0].tv_nsec = times[1].tv_nsec = 0;
int ret = futimens(fd, times);
if(ret != 0)
{
unlink((root + "/" + rinfo.name).Buf());
return {pref, "Can't set mtime for file: " + root + "/" + rinfo.name};
}
}
return Error();
}
Error RemoveFile(const struct FileInfo& linfo)
{
const static MString pref = "RemoveFile";
message("Remove " + linfo.url);
int ret = unlink(linfo.url.Buf());
if(ret != 0) return {pref, "Can't remove file " + linfo.url};
return Error();
}
Error UpdateFile(const CURLRAII& chandle, const struct FileInfo& rinfo, const struct FileInfo& linfo, const MString& root)
{
const static MString pref = "UpdateFile";
message("Update " + linfo.url);
auto rm = RemoveFile(linfo);
if(!rm) return rm.Add(pref, "Can't remove file");
auto df = DownloadFile(chandle, rinfo, root);
if(!df) return df.Add(pref, "Can't download file");
return Error();
}

168
src/ncfilew.cpp

@ -1,143 +1,105 @@
#define MICHLIB_NOSOURCE
#include "ncfilew.h"
MString NCFileW::CreateFile(NCFileW::Type stype, const MString& name, int compression, size_t nx, size_t ny)
MString NCFileW::CreateFile(NCFileW::Type stype, const MString& name, const MString& history, int compression, size_t nx, size_t ny)
{
if(stype == UNKNOWN) return "Can't determine file type";
compress = compression;
const float node_offset = 0.0;
int ret;
MString text;
Open(name);
if(!*this) return "Can't create netcdf file " + name + ": " + ErrMessage();
ret = nc_create(name.Buf(), NC_CLOBBER | NC_NETCDF4, &ncid);
if(ret != NC_NOERR) return "Can't create netcdf file: " + name;
AddAtt("node_offset", node_offset);
ret = nc_put_att_text(ncid, NC_GLOBAL, "history", history.Len() + 1, history.Buf());
if(ret != NC_NOERR) return "Can't write history attribute in the netcdf file";
switch(stype)
{
case(PSET):
case(G1V1):
{
AddDim("i", nx);
AddVar("x", NC_FLOAT, "i");
AddVar("y", NC_FLOAT, "i");
ret = nc_def_dim(ncid, "i", nx, &xdimid);
if(ret != NC_NOERR) return "Can't create dimension in the netcdf file";
ret = nc_def_var(ncid, "longitude", NC_FLOAT, 1, &xdimid, &xid);
if(ret != NC_NOERR) return "Can't create longitude variable in the netcdf file";
ret = nc_def_var(ncid, "latitude", NC_FLOAT, 1, &xdimid, &yid);
if(ret != NC_NOERR) return "Can't create latitude variable in the netcdf file";
break;
}
case(GPSET):
case(G1V2):
{
AddDim("i", nx);
AddVar("longitude", NC_FLOAT, "i");
AddVar("latitude", NC_FLOAT, "i");
ret = nc_def_dim(ncid, "longitude", nx, &xdimid);
if(ret != NC_NOERR) return "Can't create x-dimension in the netcdf file";
ret = nc_def_dim(ncid, "latitude", ny, &ydimid);
if(ret != NC_NOERR) return "Can't create y-dimension in the netcdf file";
ret = nc_def_var(ncid, "longitude", NC_FLOAT, 1, &xdimid, &xid);
if(ret != NC_NOERR) return "Can't create longitude variable in the netcdf file";
ret = nc_def_var(ncid, "latitude", NC_FLOAT, 1, &ydimid, &yid);
if(ret != NC_NOERR) return "Can't create latitude variable in the netcdf file";
break;
}
case(RGRID):
case(G2V2):
{
AddDim("x", nx);
AddDim("y", ny);
AddVar("x", NC_FLOAT, "x");
AddVar("y", NC_FLOAT, "y");
break;
}
case(GRGRID):
{
AddDim("longitude", nx);
AddDim("latitude", ny);
AddVar("longitude", NC_FLOAT, "longitude");
AddVar("latitude", NC_FLOAT, "latitude");
break;
}
case(GRID):
{
AddDim("x", nx);
AddDim("y", ny);
AddVar("x", NC_FLOAT, "y", "x");
AddVar("y", NC_FLOAT, "y", "x");
break;
}
case(GGRID):
{
AddDim("longitude", nx);
AddDim("latitude", ny);
AddVar("longitude", NC_FLOAT, "latitude", "longitude");
AddVar("latitude", NC_FLOAT, "latitude", "longitude");
ret = nc_def_dim(ncid, "longitude", nx, &xdimid);
if(ret != NC_NOERR) return "Can't create x-dimension in the netcdf file";
ret = nc_def_dim(ncid, "latitude", ny, &ydimid);
if(ret != NC_NOERR) return "Can't create y-dimension in the netcdf file";
ret = nc_def_var(ncid, "longitude", NC_FLOAT, 2, dimid, &xid);
if(ret != NC_NOERR) return "Can't create longitude variable in the netcdf file";
ret = nc_def_var(ncid, "latitude", NC_FLOAT, 2, dimid, &yid);
if(ret != NC_NOERR) return "Can't create latitude variable in the netcdf file";
break;
}
case(UNKNOWN): return "Can't determine file type";
}
if(IsGeoType(stype))
{
SetComp("longitude", compress);
SetComp("latitude", compress);
AddAtt("longitude", "standard_name", "longitude");
AddAtt("longitude", "long_name", "Longitude");
AddAtt("latitude", "standard_name", "latitude");
AddAtt("latitude", "long_name", "Latitude");
}
else
{
SetComp("x", compress);
SetComp("y", compress);
AddAtt("x", "long_name", "x-coordinate");
AddAtt("y", "long_name", "y-coordinate");
}
if(!*this) return "Can't set grid in the netcdf file " + name + ": " + ErrMessage();
ret = nc_def_var_deflate(ncid, xid, 1, 1, compress);
if(ret != NC_NOERR) return "Can't set deflate parameters for longitude variable in the netcdf file";
ret = nc_def_var_deflate(ncid, yid, 1, 1, compress);
if(ret != NC_NOERR) return "Can't set deflate parameters for latitude variable in the netcdf file";
type = stype;
return "";
}
MString NCFileW::AddTimeData(const TimeData& tdata, bool tisindex)
{
tdep = tisindex;
AddDim("time", tdata.steps.size());
AddVar("time", Type2NCType<decltype(tdata.steps)::value_type>, "time");
SetComp("time", compress);
AddAtt("time", "standard_name", "time");
AddAtt("time", "long_name", "time");
AddAtt("time", "units", tdata.UnitName());
WriteVar("time", tdata.steps.data());
if(!*this) return MString("Can't add time data to the netcdf file: ") + ErrMessage();
text = "longitude";
ret = nc_put_att_text(ncid, xid, "standard_name", text.Len() + 1, text.Buf());
if(ret != NC_NOERR) return "Can't write standard_name attribute of longitude variable in the netcdf file";
text = "latitude";
ret = nc_put_att_text(ncid, yid, "standard_name", text.Len() + 1, text.Buf());
if(ret != NC_NOERR) return "Can't write standard_name attribute of latitude variable in the netcdf file";
type = stype;
return "";
}
MString NCFileW::AddVariable(const MString& name, const MString& stname, const MString& lname, const MString& units, const MString& comment)
{
if(type == UNKNOWN) return "File not opened";
if(HaveVar(name)) return "Variable " + name + " already defined";
if(Is1DType(type))
{
if(tdep)
AddVar(name, NC_FLOAT, "time", "i");
else
AddVar(name, NC_FLOAT, "i");
}
else if(IsGeoType(type))
{
if(tdep)
AddVar(name, NC_FLOAT, "time", "latitude", "longitude");
else
AddVar(name, NC_FLOAT, "latitude", "longitude");
}
else
{
if(tdep)
AddVar(name, NC_FLOAT, "time", "y", "x");
struct Var v(name, 0);
int ret;
if(type == G1V1)
ret = nc_def_var(ncid, v.name.Buf(), NC_FLOAT, 1, &xdimid, &v.id);
else
AddVar(name, NC_FLOAT, "y", "x");
}
ret = nc_def_var(ncid, v.name.Buf(), NC_FLOAT, 2, dimid, &v.id);
if(ret != NC_NOERR) return "Can't create " + v.name + " variable in the netcdf file";
ret = nc_def_var_deflate(ncid, v.id, 1, 1, compress);
if(ret != NC_NOERR) return "Can't set deflate parameters for " + v.name + " variable in the netcdf file";
SetComp(name, compress);
if(stname.Exist()) AddAtt(name, "standard_name", stname);
if(lname.Exist()) AddAtt(name, "long_name", lname);
if(units.Exist()) AddAtt(name, "units", units);
if(comment.Exist()) AddAtt(name, "comment", comment);
AddAtt(name, "_FillValue", fill);
if(stname.Exist()) ret = nc_put_att_text(ncid, v.id, "standard_name", stname.Len() + 1, stname.Buf());
if(ret != NC_NOERR) return "Can't write standard_name attribute of " + v.name + " variable in the netcdf file";
if(lname.Exist()) ret = nc_put_att_text(ncid, v.id, "long_name", lname.Len() + 1, lname.Buf());
if(ret != NC_NOERR) return "Can't write long_name attribute of " + v.name + " variable in the netcdf file";
if(units.Exist()) ret = nc_put_att_text(ncid, v.id, "units", units.Len() + 1, units.Buf());
if(ret != NC_NOERR) return "Can't write units attribute of " + v.name + " variable in the netcdf file";
if(comment.Exist()) ret = nc_put_att_text(ncid, v.id, "comment", comment.Len() + 1, comment.Buf());
if(ret != NC_NOERR) return "Can't write comment attribute of " + v.name + " variable in the netcdf file";
if(!*this) return "Can't add variable " + name + ": " + ErrMessage();
ret = nc_put_att_float(ncid, v.id, "_FillValue", NC_FLOAT, 1, &fill);
if(ret != NC_NOERR) return "Can't write _FillValue attribute of " + v.name + " variable in the netcdf file";
vars.push_back(v);
return "";
}

129
src/ncfuncs.cpp

@ -1,9 +1,9 @@
#define MICHLIB_NOSOURCE
#include "ncfuncs.h"
NCFuncs::DimNames NCFuncs::GetDNames(const NCFileA& nc)
NCFuncs::CoordNames NCFuncs::GetDNames(const NCFileA& nc)
{
DimNames out;
CoordNames out;
auto head = nc.Header();
for(const auto& dim: head.Dimensions())
{
@ -31,36 +31,6 @@ NCFuncs::DimNames NCFuncs::GetDNames(const NCFileA& nc)
return out;
}
NCFuncs::DimNames NCFuncs::GetDNames(const NCZarr& nc)
{
DimNames out;
for(const auto& v: nc.VarNames())
for(const auto& dim: nc.DimNames(v))
{
if(dim == "lon" || dim == "longitude")
{
out.lonname = dim;
out.nx = nc.DimSize(v, dim);
}
if(dim == "lat" || dim == "latitude")
{
out.latname = dim;
out.ny = nc.DimSize(v, dim);
}
if(dim == "depth" || dim == "elevation")
{
out.depthname = dim;
out.nz = nc.DimSize(v, dim);
}
if(dim == "time")
{
out.timename = dim;
out.nt = nc.DimSize(v, dim);
}
}
return out;
}
NCFuncs::CoordNames NCFuncs::GetCNames(const NCFileA& nc)
{
CoordNames out;
@ -85,40 +55,12 @@ NCFuncs::CoordNames NCFuncs::GetCNames(const NCFileA& nc)
if(islat) out.latname = v.Name();
if(isdepth) out.depthname = v.Name();
if(istime) out.timename = v.Name();
}
return out;
}
NCFuncs::CoordNames NCFuncs::GetCNames(const NCZarr& nc)
{
CoordNames out;
for(const auto& v: nc.VarNames()) // Try to define coordinates by attribute standard_name or attribute axis
{
auto havestname = nc.HasAtt(v, "standard_name");
auto haveaxis = nc.HasAtt(v, "axis");
if(!(havestname || haveaxis)) continue;
auto stname = nc.AttString(v, "standard_name");
auto axis = nc.AttString(v, "axis");
bool islon = false, islat = false, isdepth = false, istime = false;
if(stname == "longitude") islon = true;
if(stname == "latitude") islat = true;
if(stname == "depth") isdepth = true;
if(stname == "time") istime = true;
if(!out.lonname.Exist() && axis == "X") islon = true;
if(!out.latname.Exist() && axis == "Y") islat = true;
if(!out.depthname.Exist() && axis == "Z") isdepth = true;
if(!out.timename.Exist() && axis == "T") istime = true;
if(islon) out.lonname = v;
if(islat) out.latname = v;
if(isdepth) out.depthname = v;
if(istime) out.timename = v;
if(islon) out.nx = v.Dimensions().size();
if(islat) out.ny = v.Dimensions().size();
if(isdepth) out.nz = v.Dimensions().size();
if(istime) out.nt = v.Dimensions().size();
}
// If time not found just check variable "time"
if(!out.timename.Exist() && nc.HasVar("time")) out.timename = "time";
return out;
}
@ -137,26 +79,6 @@ void NCFuncs::GetVars(const NCFileA& nc, std::set<MString>& vars)
if(vars.contains("u") && vars.contains("v")) vars.emplace("U");
if(vars.contains("u") && vars.contains("v")) vars.emplace("U2");
if(vars.contains("ssh")) vars.emplace("ugeo");
if(vars.contains("ssh")) vars.emplace("vgeo");
}
void NCFuncs::GetVars(const NCZarr& nc, std::set<MString>& vars)
{
for(const auto& v: nc.VarNames())
{
if(!nc.HasAtt(v, "standard_name")) continue;
auto ret = nc.AttString(v, "standard_name");
if(StName2Name(ret).Exist()) vars.emplace(StName2Name(ret));
}
if((vars.contains("ptemp") || vars.contains("temp")) && vars.contains("sal")) vars.emplace("pdens");
if(vars.contains("ptemp") && vars.contains("sal")) vars.emplace("temp");
if(vars.contains("temp") && vars.contains("sal")) vars.emplace("ptemp");
if(vars.contains("u") && vars.contains("v")) vars.emplace("U");
if(vars.contains("u") && vars.contains("v")) vars.emplace("U2");
if(vars.contains("ssh")) vars.emplace("ugeo");
if(vars.contains("ssh")) vars.emplace("vgeo");
}
std::tuple<MDateTime, time_t, bool> NCFuncs::Refdate(const MString& refdate)
@ -169,7 +91,6 @@ std::tuple<MDateTime, time_t, bool> NCFuncs::Refdate(const MString& refdate)
auto ci = words.begin();
if(ci != words.end())
{
if(*ci == "seconds") step = 1;
if(*ci == "minutes") step = 60;
if(*ci == "hours") step = 3600;
if(*ci == "days") step = 3600 * 24;
@ -193,16 +114,15 @@ MString NCFuncs::StName2Name(const MString& stname)
if(stname == "sea_surface_elevation") return "ssh";
if(stname == "eastward_sea_water_velocity") return "u";
if(stname == "northward_sea_water_velocity") return "v";
if(stname == "surface_geostrophic_eastward_sea_water_velocity") return "u";
if(stname == "surface_geostrophic_northward_sea_water_velocity") return "v";
if(stname == "upward_sea_water_velocity") return "w";
if(stname == "surface_geostrophic_eastward_sea_water_velocity") return "ugs";
if(stname == "surface_geostrophic_northward_sea_water_velocity") return "vgs";
if(stname == "mass_concentration_of_chlorophyll_a_in_sea_water") return "chl";
if(stname == "mole_concentration_of_nitrate_in_sea_water") return "NO3";
if(stname == "net_primary_production_of_biomass_expressed_as_carbon_per_unit_volume_in_sea_water") return "prprod";
if(stname == "mole_concentration_of_phytoplankton_expressed_as_carbon_in_sea_water") return "Cchl";
if(stname == "mole_concentration_of_phosphate_in_sea_water") return "PO4";
if(stname == "mole_concentration_of_silicate_in_sea_water") return "Si";
if(stname == "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water") return "O2";
return "";
}
@ -216,39 +136,17 @@ MString NCFuncs::Name2StName(const MString& name)
if(name == "u") return "eastward_sea_water_velocity";
if(name == "v") return "northward_sea_water_velocity";
if(name == "w") return "upward_sea_water_velocity";
if(name == "ugs") return "surface_geostrophic_eastward_sea_water_velocity";
if(name == "vgs") return "surface_geostrophic_northward_sea_water_velocity";
if(name == "chl") return "mass_concentration_of_chlorophyll_a_in_sea_water";
if(name == "NO3") return "mole_concentration_of_nitrate_in_sea_water";
if(name == "prprod") return "net_primary_production_of_biomass_expressed_as_carbon_per_unit_volume_in_sea_water";
if(name == "Cchl") return "mole_concentration_of_phytoplankton_expressed_as_carbon_in_sea_water";
if(name == "PO4") return "mole_concentration_of_phosphate_in_sea_water";
if(name == "Si") return "mole_concentration_of_silicate_in_sea_water";
if(name == "O2") return "mole_concentration_of_dissolved_molecular_oxygen_in_sea_water";
return "";
}
MString NCFuncs::Name2LongName(const MString& name)
{
if(name == "ptemp") return "Potential temperature";
if(name == "temp") return "Temperature";
if(name == "sal") return "Salinity";
if(name == "mld") return "Mixed layer depth";
if(name == "ssh") return "Sea surface height";
if(name == "u") return "X-velocity";
if(name == "v") return "Y-velocity";
if(name == "w") return "Z-velocity";
if(name == "ugeo") return "Geostrophic eastward velocity from ssh";
if(name == "vgeo") return "Geostrophic northward velocity from ssh";
if(name == "ugs") return "Geostrophic eastward velocity";
if(name == "vgs") return "Geostrophic northward velocity";
if(name == "chl") return "Concentration of chlorophyll";
if(name == "NO3") return "Concentration of nitrates";
if(name == "prprod") return "Primary production";
if(name == "Cchl") return "Concentration of chlorophyll carbon";
if(name == "PO4") return "Concentration of phosphates";
if(name == "Si") return "Concentration of silicates";
if(name == "O2") return "Concentration of dissolved oxygen";
if(name == "U") return "Module of horizontal velocity";
if(name == "U2") return "Squared horizontal velocity";
return "";
@ -265,14 +163,3 @@ bool NCFuncs::HaveVar(const NCFileA& nc, const MString& vname)
}
return false;
}
bool NCFuncs::HaveVar(const NCZarr& nc, const MString& vname)
{
for(const auto& v: nc.VarNames())
{
if(!nc.HasAtt(v, "standard_name")) continue;
auto stname = nc.AttString(v, "standard_name");
if(StName2Name(stname) == vname) return true;
}
return false;
}

231
src/ncsimple.cpp

@ -1,231 +0,0 @@
#define MICHLIB_NOSOURCE
#include "ncsimple.h"
RetVal<std::vector<NCSimpleFunctions::Attribute>> NCSimpleFunctions::ReadAtts(int vid) const
{
static const MString pref = "NCSimple::ReadAtts";
int natt;
int ret;
if(vid == NC_GLOBAL)
ret = nc_inq_natts(ncid, &natt);
else
ret = nc_inq_var(ncid, vid, nullptr, nullptr, nullptr, nullptr, &natt);
if(ret != NC_NOERR) return Error(pref, MString("Can't inquire number of attributes: ") + nc_strerror(ret));
std::vector<Attribute> out;
char name[NC_MAX_NAME + 1];
for(int aid = 0; aid < natt; aid++)
{
nc_type type;
size_t len;
ret = nc_inq_attname(ncid, vid, aid, name);
if(ret != NC_NOERR) return Error(pref, MString("Can't inquire attribute name: ") + nc_strerror(ret));
ret = nc_inq_atttype(ncid, vid, name, &type);
if(ret != NC_NOERR) return Error(pref, MString("Can't inquire attribute type: ") + nc_strerror(ret));
ret = nc_inq_attlen(ncid, vid, name, &len);
if(ret != NC_NOERR) return Error(pref, MString("Can't inquire attribute length: ") + nc_strerror(ret));
if(type == NC_DOUBLE || type == NC_FLOAT)
{
if(len == 1)
{
double d;
ret = nc_get_att_double(ncid, vid, name, &d);
if(ret != NC_NOERR) return Error(pref, MString("Can't read attribute ") + name + ": " + nc_strerror(ret));
out.emplace_back(MString(name), d);
}
else
{
std::vector<double> dd(len);
ret = nc_get_att_double(ncid, vid, name, dd.data());
if(ret != NC_NOERR) return Error(pref, MString("Can't read attribute ") + name + ": " + nc_strerror(ret));
for(size_t i = 0; i < dd.size(); i++) out.emplace_back(MString(name) + "[" + i + "]", dd[i]);
}
}
else if(type == NC_BYTE || type == NC_SHORT || type == NC_INT || type == NC_INT64)
{
if(len == 1)
{
long long i;
ret = nc_get_att_longlong(ncid, vid, name, &i);
if(ret != NC_NOERR) return Error(pref, MString("Can't read attribute ") + name + ": " + nc_strerror(ret));
out.emplace_back(MString(name), int_cast<int8>(i));
}
else
{
std::vector<long long> ii(len);
ret = nc_get_att_longlong(ncid, vid, name, ii.data());
if(ret != NC_NOERR) return Error(pref, MString("Can't read attribute ") + name + ": " + nc_strerror(ret));
for(size_t i = 0; i < ii.size(); i++) out.emplace_back(MString(name) + "[" + i + "]", int_cast<int8>(ii[i]));
}
}
else if(type == NC_UBYTE || type == NC_USHORT || type == NC_UINT || type == NC_UINT64)
{
if(len == 1)
{
unsigned long long u;
ret = nc_get_att_ulonglong(ncid, vid, name, &u);
if(ret != NC_NOERR) return Error(pref, MString("Can't read attribute ") + name + ": " + nc_strerror(ret));
out.emplace_back(MString(name), int_cast<uint8>(u));
}
else
{
std::vector<unsigned long long> uu(len);
ret = nc_get_att_ulonglong(ncid, vid, name, uu.data());
if(ret != NC_NOERR) return Error(pref, MString("Can't read attribute ") + name + ": " + nc_strerror(ret));
for(size_t i = 0; i < uu.size(); i++) out.emplace_back(MString(name) + "[" + i + "]", int_cast<uint8>(uu[i]));
}
}
else if(type == NC_CHAR)
{
std::vector<char> ss(len + 1, 0);
ret = nc_get_att_text(ncid, vid, name, ss.data());
if(ret != NC_NOERR) return Error(pref, MString("Can't read attribute ") + name + ": " + nc_strerror(ret));
out.emplace_back(MString(name), MString(ss.data()));
}
else
return Error(pref, MString("Unsupported type of attribute ") + name);
// Ignore all other types
}
return out;
}
Error NCSimpleFunctions::Open(const MString& filename)
{
static const MString pref = "NCSimple::Open";
// Cleanup
gats.clear();
dims.clear();
vars.clear();
nc_close(ncid);
std::vector<Attribute> newgats;
std::vector<Dimension> newdims;
std::vector<Variable> newvars;
char name[NC_MAX_NAME + 1];
// Open
{
auto ret = nc_open(filename.Buf(), 0, &ncid);
if(ret != NC_NOERR) return Error(pref, "Can't open file " + filename + ": " + nc_strerror(ret));
}
// Dimensions
{
int ndim;
auto ret = nc_inq_dimids(ncid, &ndim, nullptr, 1);
if(ret != NC_NOERR) return Error(pref, "Can't inquire number of dimensions in file " + filename + ": " + nc_strerror(ret));
std::vector<int> dimids(ndim);
ret = nc_inq_dimids(ncid, nullptr, dimids.data(), 1);
if(ret != NC_NOERR) return Error(pref, "Can't inquire dimension ids in file " + filename + ": " + nc_strerror(ret));
size_t len;
for(const auto id: dimids)
{
ret = nc_inq_dim(ncid, id, name, &len);
if(ret != NC_NOERR) return Error(pref, "Can't inquire dimension name and size in file " + filename + ": " + nc_strerror(ret));
newdims.emplace_back(name, len);
}
}
// Global attributes
{
auto ret = ReadAtts(NC_GLOBAL);
if(!ret) return ret.Add(pref, "Can't read global attributes in file " + filename);
newgats = std::move(ret.Value());
}
// Variables
{
int nvar;
auto ret = nc_inq_varids(ncid, &nvar, nullptr);
if(ret != NC_NOERR) return Error(pref, "Can't inquire number of variables in file " + filename + ": " + nc_strerror(ret));
std::vector<int> varids(nvar);
ret = nc_inq_varids(ncid, nullptr, varids.data());
if(ret != NC_NOERR) return Error(pref, "Can't inquire variables ids in file " + filename + ": " + nc_strerror(ret));
for(const auto vid: varids)
{
nc_type nctype;
int ndim;
auto ret = nc_inq_var(ncid, vid, name, &nctype, &ndim, nullptr, nullptr);
if(ret != NC_NOERR) return Error(pref, "Can't inquire variable info in file " + filename + ": " + nc_strerror(ret));
VarType vt = VarType::UNDEF;
if(nctype == NC_FLOAT) vt = VarType::FLOAT;
if(nctype == NC_DOUBLE) vt = VarType::DOUBLE;
if(nctype == NC_BYTE) vt = VarType::INT1;
if(nctype == NC_SHORT) vt = VarType::INT2;
if(nctype == NC_INT) vt = VarType::INT4;
if(nctype == NC_INT64) vt = VarType::INT8;
if(nctype == NC_UBYTE) vt = VarType::UINT1;
if(vt == VarType::UNDEF) return Error(pref, "Unsupported type of variable " + MString(name) + " in file " + filename);
std::vector<int> dimids(ndim);
ret = nc_inq_vardimid(ncid, vid, dimids.data());
if(ret != NC_NOERR) return Error(pref, "Can't inquire variable dimensions in file " + filename + ": " + nc_strerror(ret));
std::vector<size_t> dims;
char dname[NC_MAX_NAME + 1];
for(const auto did: dimids)
{
auto ret = nc_inq_dimname(ncid, did, dname);
if(ret != NC_NOERR) return Error(pref, "Can't inquire dimension name in file " + filename + ": " + nc_strerror(ret));
size_t ind = newdims.size();
for(size_t i = 0; i < newdims.size() && ind == newdims.size(); i++)
if(dname == newdims[i].Name()) ind = i;
if(ind == newdims.size()) return Error(pref, "Can't find dimension " + MString(dname) + " of variable " + name + " in file " + filename);
dims.push_back(ind);
}
auto atts = ReadAtts(vid);
const char fname[] = "_FillValue";
if(!atts) return Error(pref, "Can't get attributes of variable " + MString(name) + " in file " + filename);
std::vector<Attribute> vatts = std::move(atts.Value());
Variable::FillType fill;
if(FindInd(fname, vatts) != vatts.size())
{
if(nctype == NC_FLOAT || nctype == NC_DOUBLE)
{
double d;
auto ret = nc_get_att_double(ncid, vid, fname, &d);
if(ret != NC_NOERR) return Error(pref, "Can't get fill value for the variable " + MString(name) + " in file " + filename + ": " + nc_strerror(ret));
fill = d;
}
if(nctype == NC_BYTE || nctype == NC_SHORT || nctype == NC_INT || nctype == NC_INT64)
{
long long l;
auto ret = nc_get_att_longlong(ncid, vid, fname, &l);
if(ret != NC_NOERR) return Error(pref, "Can't get fill value for the variable " + MString(name) + " in file " + filename + ": " + nc_strerror(ret));
fill = int_cast<int8>(l);
}
if(nctype == NC_UBYTE || nctype == NC_USHORT || nctype == NC_UINT || nctype == NC_UINT64)
{
unsigned long long u;
auto ret = nc_get_att_ulonglong(ncid, vid, fname, &u);
if(ret != NC_NOERR) return Error(pref, "Can't get fill value for the variable " + MString(name) + " in file " + filename + ": " + nc_strerror(ret));
fill = int_cast<uint8>(u);
}
}
newvars.emplace_back(name, vt, std::move(dims), std::move(vatts), fill);
}
}
gats = std::move(newgats);
dims = std::move(newdims);
vars = std::move(newvars);
return Error();
}

250
src/zarr.cpp

@ -1,250 +0,0 @@
#define MICHLIB_NOSOURCE
#include "zarr.h"
#include "copcat.h"
#include <blosc.h>
std::vector<MString> ZarrFunctions::ReadVarNames(const Json::Value& meta)
{
std::vector<MString> out;
if(meta.type() != Json::objectValue) return out;
const auto keys = meta.getMemberNames();
for(const auto& key: keys)
{
if(!key.ends_with("/.zarray")) continue;
const auto vname = key.substr(0, key.size() - 8);
const auto& zattr = meta[vname + "/.zattrs"];
if(!(zattr && zattr.type() == Json::objectValue)) continue;
MString name(vname.c_str(), vname.size());
bool found = false;
for(size_t id = 0; id < out.size(); id++)
if(out[id] == name)
{
found = true;
break;
}
if(!found) out.emplace_back(std::move(name));
}
return out;
}
Error ZarrFunctions::AddVar(const MString& name, const Json::Value& zattrs, const Json::Value& zarray)
{
static const MString pref = "Zarr::AddVar";
VarType newtype;
Variable::FillType fill;
// Checks for parameters in zarray
{
const auto& cid = zarray["compressor"]["id"];
if(!cid || cid.type() != Json::stringValue || cid.asString() != "blosc") return {pref, "Unsupported compressor: " + MString(cid.asString().c_str())};
}
{
const auto& zf = zarray["zarr_format"];
if(!zf || (zf.type() != Json::uintValue && zf.type() != Json::intValue) || zf.asUInt() != 2) return {pref, "Unsupported format version: " + MString(zf.asUInt())};
}
{
const auto& ord = zarray["order"];
if(!ord || ord.type() != Json::stringValue || ord.asString() != "C") return {pref, "Order in not C"};
}
{
const auto& f = zarray["filters"];
if(f.type() != Json::nullValue) return {pref, "Filters is not null"};
}
// Read dtype
{
const auto& dtype = zarray["dtype"];
if(!dtype || dtype.type() != Json::stringValue) return {pref, "No datatype"};
const auto str = dtype.asString();
if(str == "<f4")
newtype = VarType::FLOAT;
else if(str == "<f8")
newtype = VarType::DOUBLE;
else if(str == "|i1")
newtype = VarType::INT1;
else if(str == "|u1")
newtype = VarType::UINT1;
else if(str == "<i2")
newtype = VarType::INT2;
else if(str == "<i4")
newtype = VarType::INT4;
else if(str == "<i8")
newtype = VarType::INT8;
else
return {pref, "Unsupported datatype: " + MString(str.c_str())};
}
// Read fill_value
{
const auto& fillval = zarray["fill_value"];
if(!fillval) // return {pref, "No fillval"};
fill = 0;
else if(fillval.type() == Json::uintValue)
fill = fillval.asUInt64();
else if(fillval.type() == Json::intValue)
fill = fillval.asInt64();
else if(fillval.type() == Json::realValue)
fill = fillval.asDouble();
else if(fillval.type() == Json::stringValue && fillval.asString() == "NaN")
fill = NAN;
}
// Read attributes
auto atts = ReadAtts(zattrs);
std::vector<MString> dnames;
std::vector<size_t> dsizes;
std::vector<size_t> csizes;
std::vector<size_t> dids;
// Read dimensions names
{
const auto& arrdim = zattrs["_ARRAY_DIMENSIONS"];
if(!(arrdim && arrdim.type() == Json::arrayValue)) return {pref, "_ARRAY_DIMENSIONS not found"};
for(Json::ArrayIndex i = 0; i < arrdim.size(); i++)
if(const auto& dim = arrdim[i]; dim.type() == Json::stringValue)
{
const auto val = dim.asString();
dnames.emplace_back(val.c_str(), val.size());
}
}
// Read dimensions sizes
{
const auto& shape = zarray["shape"];
if(!(shape && shape.type() == Json::arrayValue)) return {pref, "shape not found"};
for(Json::ArrayIndex i = 0; i < shape.size(); i++)
if(const auto& s = shape[i]; s.type() == Json::uintValue || s.type() == Json::intValue) dsizes.push_back(s.asUInt());
}
// Read chunk sizes
{
const auto& chunk = zarray["chunks"];
if(!(chunk && chunk.type() == Json::arrayValue)) return {pref, "chunks not found"};
for(Json::ArrayIndex i = 0; i < chunk.size(); i++)
if(const auto& c = chunk[i]; c.type() == Json::uintValue || c.type() == Json::intValue) csizes.push_back(c.asUInt());
}
if(dnames.size() != dsizes.size() || dnames.size() != csizes.size()) return {pref, "shape and chunks are in contradiction"};
dids.resize(dnames.size());
// Check dimensions names and sizes
for(size_t i = 0; i < dnames.size(); i++)
{
bool found = false;
for(size_t id = 0; id < dims.size(); id++)
if(dims[id].Name() == dnames[i])
{
found = true;
if(dims[id].Size() != dsizes[i])
return {pref, "According to previous data, the dimension " + dnames[i] + " has a size of " + dims[id].Size() + ", but here it is defined as " + dsizes[i]};
dids[i] = id;
break;
}
if(!found)
{
dids[i] = dims.size();
dims.emplace_back(dnames[i], dsizes[i]);
}
}
vars.emplace_back(name, newtype, std::move(dids), std::move(atts), fill);
chunks.push_back(std::move(csizes));
return Error();
}
Error ZarrFunctions::GetChunk(const MString& var, const std::vector<size_t>& chunkind, size_t chunksize, size_t elsize, void* data, const void* fill) const
{
static const MString pref = "Zarr::GetChunk";
MString str = url + "/" + var + "/";
for(size_t i = 0; i < chunkind.size(); i++) str += (i == 0 ? "" : ".") + MString(chunkind[i]);
auto [content, suc] = cache->Get(str);
if(!suc)
{
michlib::message(str + " not found in cache, downloading");
CURLRAII myhandle; // TODO: remove this workaround of unknown bug
if(proxyurl.Exist()) curl_easy_setopt(myhandle, CURLOPT_PROXY, proxyurl.Buf());
//auto [out, res] = GetUrl(chandle, str);
auto [out, res] = GetUrl(myhandle, str);
if(res != CURLE_OK) return Error(pref, MString("can't download chunk: ") + chandle.Err());
long respcode;
//curl_easy_getinfo(chandle, CURLINFO_RESPONSE_CODE, &respcode);
curl_easy_getinfo(myhandle, CURLINFO_RESPONSE_CODE, &respcode);
if(respcode == 403) out = ""; // Failed chunk download mean that this chunk contains only fill
cache->Put(str, out, 3600);
content = std::move(out);
}
if(content.Exist())
{
size_t nb, cb, bs;
blosc_cbuffer_sizes(content.Buf(), &nb, &cb, &bs);
if(cb != content.Len()) return Error(pref, MString("bytes download: ") + content.Len() + ", but compressed bytes " + cb);
if(nb != chunksize * elsize) return Error(pref, MString("decompressed bytes: ") + nb + ", but buffer size " + chunksize * elsize);
auto res = blosc_decompress_ctx(content.Buf(), data, chunksize * elsize, 1);
if(int_cast<size_t>(res) != chunksize * elsize) return Error(pref, MString("decompress only ") + res + " bytes of " + chunksize * elsize);
}
else
{
if(fill == nullptr) return Error(pref, MString("can't download chunk: ") + chandle.Err());
for(size_t i = 0; i < chunksize; i++) memcpy(michlib::P1(data) + i * elsize, fill, elsize);
}
return Error();
}
Error ZarrFunctions::Open(const MString& product, const MString& dataset, bool time)
{
static const MString pref = "Zarr::Open";
gats.clear();
dims.clear();
vars.clear();
CopernicusCatalog cat;
Json::Value json;
MString realdataset;
if(!dataset.Exist())
{
auto dsets = cat.DatasetList(product);
if(!dsets) return dsets.Add(pref, "Can't get default dataset of product " + product);
realdataset = dsets.Value()[0];
}
else
realdataset = dataset;
{
auto urlret = time ? cat.DatasetTimeURL(product, realdataset) : cat.DatasetGeoURL(product, realdataset);
if(!urlret) return urlret.Add(pref, "Can't get url for the dataset " + realdataset + " of product " + product);
url = urlret.Value();
auto ret = cat.GetJSON(url + "/.zmetadata");
if(ret)
json = ret.Value();
else
return ret.Add(pref, "can't download .zmetadata");
}
const auto& meta = json["metadata"];
if(!meta) return {pref, "No \"metadata\" key in JSON data"};
if(meta[".zattrs"]) gats = ReadAtts(meta[".zattrs"]);
auto vnames = ReadVarNames(meta);
for(size_t i = 0; i < vnames.size(); i++)
{
auto err = AddVar(vnames[i], meta[(vnames[i] + "/.zattrs").Buf()], meta[(vnames[i] + "/.zarray").Buf()]);
if(!err) return err.Add(pref, "Can't init variable " + vnames[i]);
}
return Error();
}
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