odm/include/ncfuncs.h

#pragma once
#include "DataAdapters/ncfilealt.h"
#include "basedata.h"
#include "mdatetime.h"
#include "nczarr.h"
#include <map>
#include <set>
#include <tuple>

using michlib::MDateTime;
using michlib::MString;
using michlib::NCFileA;

class NCFuncs
{
 public:
 struct CoordNames
 {
  MString lonname, latname, depthname, timename;
 };
 struct DimNames
 {
  MString lonname, latname, depthname, timename;
  size_t  nx, ny, nz, nt;
 };

 static MString                             StName2Name(const MString& stname);
 static MString                             Name2StName(const MString& name);
 static MString                             Name2LongName(const MString& name);
 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 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)
 {
  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));
    }
    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;
 }
};
Added source AVISOLOCAL and made a some code rearrangement. 2 years ago			`#pragma once`
			`#include "DataAdapters/ncfilealt.h"`
NCFuncs::CheckVar now returns a VarPresence enum instead of a bool. The calculation of derived variables has been moved to a separate function in NCFuncs. Added calculation of geostrophic velocities based on sea surface height. The uv and genintfile actions can now use geostrophic velocities. 1 year ago			`#include "basedata.h"`
Added source AVISOLOCAL and made a some code rearrangement. 2 years ago			`#include "mdatetime.h"`
Common class for NCSimple and Zarr 5 months ago			`#include "nczarr.h"`
NCFuncs::CheckVar now returns a VarPresence enum instead of a bool. The calculation of derived variables has been moved to a separate function in NCFuncs. Added calculation of geostrophic velocities based on sea surface height. The uv and genintfile actions can now use geostrophic velocities. 1 year ago			`#include <map>`
Added source AVISOLOCAL and made a some code rearrangement. 2 years ago			`#include <set>`
			`#include <tuple>`

			`using michlib::MDateTime;`
			`using michlib::MString;`
			`using michlib::NCFileA;`

			`class NCFuncs`
			`{`
			`public:`
			`struct CoordNames`
Removed some features from the NCZarr interface. Removed direct access to variables and dimensions in NCZarr, dimensions are now bound to variables. Separate CoordsNames and DimNames structures in the NCFuncs class. 5 months ago			`{`
			`MString lonname, latname, depthname, timename;`
			`};`
			`struct DimNames`
Added source AVISOLOCAL and made a some code rearrangement. 2 years ago			`{`
			`MString lonname, latname, depthname, timename;`
			`size_t nx, ny, nz, nt;`
			`};`

			`static MString StName2Name(const MString& stname);`
Added support for netcdf output for the tsc action 1 year ago			`static MString Name2StName(const MString& name);`
			`static MString Name2LongName(const MString& name);`
Added source AVISOLOCAL and made a some code rearrangement. 2 years ago			`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);`
Removed some features from the NCZarr interface. Removed direct access to variables and dimensions in NCZarr, dimensions are now bound to variables. Separate CoordsNames and DimNames structures in the NCFuncs class. 5 months ago			`static DimNames GetDNames(const NCFileA& nc);`
Added source AVISOLOCAL and made a some code rearrangement. 2 years ago			`static bool HaveVar(const NCFileA& nc, const MString& vname);`
Rewrite NEMO source for using new zarr data 7 months ago
Common class for NCSimple and Zarr 5 months ago			`static void GetVars(const NCZarr& nc, std::set<MString>& vars);`
			`static CoordNames GetCNames(const NCZarr& nc);`
Removed some features from the NCZarr interface. Removed direct access to variables and dimensions in NCZarr, dimensions are now bound to variables. Separate CoordsNames and DimNames structures in the NCFuncs class. 5 months ago			`static DimNames GetDNames(const NCZarr& nc);`
Common class for NCSimple and Zarr 5 months ago			`static bool HaveVar(const NCZarr& nc, const MString& vname);`
Rewrite NEMO source for using new zarr data 7 months ago
			`template<class HV> static VarPresence CheckVar(const MString& vname, HV hv)`
Added source AVISOLOCAL and made a some code rearrangement. 2 years ago			`{`
			`if(!hv(vname))`
			`{`
NCFuncs::CheckVar now returns a VarPresence enum instead of a bool. The calculation of derived variables has been moved to a separate function in NCFuncs. Added calculation of geostrophic velocities based on sea surface height. The uv and genintfile actions can now use geostrophic velocities. 1 year ago			`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;`
Added source AVISOLOCAL and made a some code rearrangement. 2 years ago			`}`
NCFuncs::CheckVar now returns a VarPresence enum instead of a bool. The calculation of derived variables has been moved to a separate function in NCFuncs. Added calculation of geostrophic velocities based on sea surface height. The uv and genintfile actions can now use geostrophic velocities. 1 year ago			`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) {`
Common class for NCSimple and Zarr 5 months ago			`{ d->Depth(p) } -> std::convertible_to<real>;`
NCFuncs::CheckVar now returns a VarPresence enum instead of a bool. The calculation of derived variables has been moved to a separate function in NCFuncs. Added calculation of geostrophic velocities based on sea surface height. The uv and genintfile actions can now use geostrophic velocities. 1 year ago			`})`
			`{`
			`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));`
			`}`
			`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;`
Added source AVISOLOCAL and made a some code rearrangement. 2 years ago			`}`
			`};`