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Fixing compile errors on Titan

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This commit is contained in:
Mark Berrill 2017-03-01 16:30:39 -05:00
parent 90ffb5b9d0
commit 15d48e03c7
3 changed files with 410 additions and 405 deletions
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415
IO/silo.cpp
View File

@ -14,41 +14,6 @@
namespace silo {
/****************************************************
* Helper functions *
****************************************************/
template<class TYPE> static constexpr int getType();
template<> constexpr int getType<double>() { return DB_DOUBLE; }
template<> constexpr int getType<float>() { return DB_FLOAT; }
template<> constexpr int getType<int>() { return DB_INT; }
VariableDataType varDataType( DBfile *fid, const std::string& name )
{
auto type = DBGetVarType( fid, name.c_str() );
VariableDataType type2 = VariableDataType::UNKNOWN;
if ( type == DB_DOUBLE )
type2 = VariableDataType::DOUBLE;
else if ( type == DB_FLOAT )
type2 = VariableDataType::FLOAT;
else if ( type == DB_INT )
type2 = VariableDataType::INT;
return type2;
}
template<class TYPE>
static inline void copyData( Array<TYPE>& data, int type, const void *src )
{
if ( type == getType<TYPE>() )
memcpy( data.data(), src, data.length()*sizeof(TYPE) );
else if ( type == DB_DOUBLE )
data.copy<double>( static_cast<const double*>(src) );
else if ( type == DB_FLOAT )
data.copy<float>( static_cast<const float*>(src) );
else if ( type == DB_INT )
data.copy<int>( static_cast<const int*>(src) );
else
ERROR("Unknown type");
}
/****************************************************
* Open/close a file *
****************************************************/
@ -71,113 +36,25 @@ void close( DBfile* fid )
/****************************************************
* Write/read an arbitrary vector *
* Helper functions *
****************************************************/
template<class TYPE> int getSiloType();
template<> int getSiloType<int>() { return DB_INT; }
template<> int getSiloType<float>() { return DB_FLOAT; }
template<> int getSiloType<double>() { return DB_DOUBLE; }
template<class TYPE>
void write( DBfile* fid, const std::string& varname, const std::vector<TYPE>& data )
VariableDataType varDataType( DBfile *fid, const std::string& name )
{
int dims = data.size();
int err = DBWrite( fid, varname.c_str(), (void*) data.data(), &dims, 1, getSiloType<TYPE>() );
ASSERT( err == 0 );
}
template<class TYPE>
std::vector<TYPE> read( DBfile* fid, const std::string& varname )
{
int N = DBGetVarLength( fid, varname.c_str() );
std::vector<TYPE> data(N);
int err = DBReadVar( fid, varname.c_str(), data.data() );
ASSERT( err == 0 );
return data;
}
/****************************************************
* Helper function to get variable suffixes *
****************************************************/
static std::vector<std::string> getVarSuffix( int ndim, int nvars )
{
std::vector<std::string> suffix(nvars);
if ( nvars == 1 ) {
suffix[0] = "";
} else if ( nvars == ndim ) {
if ( ndim==2 ) {
suffix[0] = "_x";
suffix[1] = "_y";
} else if ( ndim==3 ) {
suffix[0] = "_x";
suffix[1] = "_y";
suffix[2] = "_z";
} else {
ERROR("Not finished");
}
} else if ( nvars == ndim*ndim ) {
if ( ndim==2 ) {
suffix[0] = "_xx";
suffix[1] = "_xy";
suffix[2] = "_yx";
suffix[3] = "_yy";
} else if ( ndim==3 ) {
suffix[0] = "_xx";
suffix[1] = "_xy";
suffix[2] = "_xz";
suffix[3] = "_yx";
suffix[4] = "_yy";
suffix[5] = "_yz";
suffix[6] = "_zx";
suffix[7] = "_zy";
suffix[8] = "_zz";
} else {
ERROR("Not finished");
}
} else {
for (int i=0; i<nvars; i++)
suffix[i] = "_" + std::to_string(i+1);
}
return suffix;
auto type = DBGetVarType( fid, name.c_str() );
VariableDataType type2 = VariableDataType::UNKNOWN;
if ( type == DB_DOUBLE )
type2 = VariableDataType::DOUBLE;
else if ( type == DB_FLOAT )
type2 = VariableDataType::FLOAT;
else if ( type == DB_INT )
type2 = VariableDataType::INT;
return type2;
}
/****************************************************
* Write/read a uniform mesh to silo *
****************************************************/
template<int NDIM>
void writeUniformMesh( DBfile* fid, const std::string& meshname,
const std::array<double,2*NDIM>& range, const std::array<int,NDIM>& N )
{
PROFILE_START("writeUniformMesh",2);
int dims[NDIM];
for (size_t d=0; d<N.size(); d++)
dims[d] = N[d]+1;
float *x = nullptr;
if ( NDIM >= 1 ) {
x = new float[dims[0]];
for (int i=0; i<N[0]; i++)
x[i] = range[0] + i*(range[1]-range[0])/N[0];
x[N[0]] = range[1];
}
float *y = nullptr;
if ( NDIM >= 2 ) {
y = new float[dims[1]];
for (int i=0; i<N[1]; i++)
y[i] = range[2] + i*(range[3]-range[2])/N[1];
y[N[1]] = range[3];
}
float *z = nullptr;
if ( NDIM >= 3 ) {
z = new float[dims[2]];
for (int i=0; i<N[2]; i++)
z[i] = range[4] + i*(range[5]-range[4])/N[2];
z[N[2]] = range[5];
}
float *coords[] = { x, y, z };
int err = DBPutQuadmesh( fid, meshname.c_str(), nullptr, coords, dims, NDIM, DB_FLOAT, DB_COLLINEAR, nullptr );
ASSERT( err == 0 );
PROFILE_STOP("writeUniformMesh",2);
}
void readUniformMesh( DBfile* fid, const std::string& meshname,
std::vector<double>& range, std::vector<int>& N )
{
@ -194,240 +71,6 @@ void readUniformMesh( DBfile* fid, const std::string& meshname,
}
/****************************************************
* Write a vector/tensor quad variable *
****************************************************/
template<int NDIM,class TYPE>
void writeUniformMeshVariable( DBfile* fid, const std::string& meshname, const std::array<int,NDIM>& N,
const std::string& varname, const Array<TYPE>& data, VariableType type )
{
PROFILE_START("writeUniformMeshVariable",2);
int nvars=1, dims[NDIM]={1};
const TYPE *vars[NDIM] = { nullptr };
int vartype = 0;
if ( type == VariableType::NodeVariable ) {
ASSERT( data.ndim()==NDIM || data.ndim()==NDIM+1 );
for (int d=0; d<NDIM; d++)
ASSERT(N[d]+1==(int)data.size(d));
vartype = DB_NODECENT;
nvars = data.size(NDIM);
size_t N = data.length()/nvars;
for (int d=0; d<NDIM; d++)
dims[d] = data.size(d);
for (int i=0; i<nvars; i++)
vars[i] = &data(i*N);
} else if ( type == VariableType::EdgeVariable ) {
ERROR("Not finished");
} else if ( type == VariableType::SurfaceVariable ) {
ERROR("Not finished");
} else if ( type == VariableType::VolumeVariable ) {
ASSERT( data.ndim()==NDIM || data.ndim()==NDIM+1 );
for (int d=0; d<NDIM; d++)
ASSERT(N[d]==(int)data.size(d));
vartype = DB_ZONECENT;
nvars = data.size(NDIM);
size_t N = data.length()/nvars;
for (int d=0; d<NDIM; d++)
dims[d] = data.size(d);
for (int i=0; i<nvars; i++)
vars[i] = &data(i*N);
} else {
ERROR("Invalid variable type");
}
auto suffix = getVarSuffix( NDIM, nvars );
std::vector<std::string> var_names(nvars);
for (int i=0; i<nvars; i++)
var_names[i] = varname + suffix[i];
std::vector<char*> varnames(nvars,nullptr);
for (int i=0; i<nvars; i++)
varnames[i] = const_cast<char*>(var_names[i].c_str());
int err = DBPutQuadvar( fid, varname.c_str(), meshname.c_str(), nvars,
varnames.data(), vars, dims, NDIM, nullptr, 0, getType<TYPE>(), vartype, nullptr );
ASSERT( err == 0 );
PROFILE_STOP("writeUniformMeshVariable",2);
}
template<class TYPE>
Array<TYPE> readUniformMeshVariable( DBfile* fid, const std::string& varname )
{
auto var = DBGetQuadvar( fid, varname.c_str() );
ASSERT( var != nullptr );
Array<TYPE> data( var->nels, var->nvals );
int type = var->datatype;
for (int i=0; i<var->nvals; i++) {
Array<TYPE> data2( var->nels );
copyData<TYPE>( data2, type, var->vals[i] );
memcpy( &data(0,i), data2.data(), var->nels*sizeof(TYPE) );
}
DBFreeQuadvar( var );
std::vector<size_t> dims( var->ndims+1, var->nvals );
for (int d=0; d<var->ndims; d++)
dims[d] = var->dims[d];
data.reshape( dims );
return data;
}
/****************************************************
* Read/write a point mesh/variable to silo *
****************************************************/
template<class TYPE>
void writePointMesh( DBfile* fid, const std::string& meshname,
int ndim, int N, const TYPE *coords[] )
{
int err = DBPutPointmesh( fid, meshname.c_str(), ndim, coords, N, getType<TYPE>(), nullptr );
ASSERT( err == 0 );
}
template<class TYPE>
Array<TYPE> readPointMesh( DBfile* fid, const std::string& meshname )
{
auto mesh = DBGetPointmesh( fid, meshname.c_str() );
int N = mesh->nels;
int ndim = mesh->ndims;
Array<TYPE> coords(N,ndim);
int type = mesh->datatype;
for (int d=0; d<ndim; d++) {
Array<TYPE> data2( N );
copyData<TYPE>( data2, type, mesh->coords[d] );
memcpy( &coords(0,d), data2.data(), N*sizeof(TYPE) );
}
DBFreePointmesh( mesh );
return coords;
}
template<class TYPE>
void writePointMeshVariable( DBfile* fid, const std::string& meshname,
const std::string& varname, const Array<TYPE>& data )
{
int N = data.size(0);
int nvars = data.size(1);
std::vector<const TYPE*> vars(nvars);
for (int i=0; i<nvars; i++)
vars[i] = &data(0,i);
int err = DBPutPointvar( fid, varname.c_str(), meshname.c_str(), nvars, vars.data(), N, getType<TYPE>(), nullptr );
ASSERT( err == 0 );
}
template<class TYPE>
Array<TYPE> readPointMeshVariable( DBfile* fid, const std::string& varname )
{
auto var = DBGetPointvar( fid, varname.c_str() );
ASSERT( var != nullptr );
Array<TYPE> data( var->nels, var->nvals );
int type = var->datatype;
for (int i=0; i<var->nvals; i++) {
Array<TYPE> data2( var->nels );
copyData<TYPE>( data2, type, var->vals[i] );
memcpy( &data(0,i), data2.data(), var->nels*sizeof(TYPE) );
}
DBFreeMeshvar( var );
return data;
}
/****************************************************
* Read/write a triangle mesh *
****************************************************/
template<class TYPE>
void writeTriMesh( DBfile* fid, const std::string& meshName,
int ndim, int ndim_tri, int N, const TYPE *coords[], int N_tri, const int *tri[] )
{
auto zoneName = meshName + "_zones";
std::vector<int> nodelist( (ndim_tri+1)*N_tri );
for (int i=0, j=0; i<N_tri; i++) {
for (int d=0; d<ndim_tri+1; d++, j++)
nodelist[j] = tri[d][i];
}
int shapetype = 0;
if ( ndim_tri==1 )
shapetype = DB_ZONETYPE_BEAM;
else if ( ndim_tri==2 )
shapetype = DB_ZONETYPE_TRIANGLE;
else if ( ndim_tri==3 )
shapetype = DB_ZONETYPE_PYRAMID;
else
ERROR("Unknown shapetype");
int shapesize = ndim_tri+1;
int shapecnt = N_tri;
DBPutZonelist2( fid, zoneName.c_str(), N_tri, ndim_tri, nodelist.data(),
nodelist.size(), 0, 0, 0, &shapetype, &shapesize, &shapecnt, 1, nullptr );
DBPutUcdmesh( fid, meshName.c_str(), ndim, nullptr, coords, N,
nodelist.size(), zoneName.c_str(), nullptr, getType<TYPE>(), nullptr );
}
template<class TYPE>
void readTriMesh( DBfile* fid, const std::string& meshname, Array<TYPE>& coords, Array<int>& tri )
{
auto mesh = DBGetUcdmesh( fid, meshname.c_str() );
int ndim = mesh->ndims;
int N_nodes = mesh->nnodes;
coords.resize(N_nodes,ndim);
int mesh_type = mesh->datatype;
for (int d=0; d<ndim; d++) {
Array<TYPE> data2( N_nodes );
copyData<TYPE>( data2, mesh_type, mesh->coords[d] );
memcpy( &coords(0,d), data2.data(), N_nodes*sizeof(TYPE) );
}
auto zones = mesh->zones;
int N_zones = zones->nzones;
int ndim_zones = zones->ndims;
ASSERT( zones->nshapes==1 );
int shape_type = zones->shapetype[0];
int shapesize = zones->shapesize[0];
tri.resize(N_zones,shapesize);
for (int i=0; i<N_zones; i++) {
for (int j=0; j<shapesize; j++)
tri(i,j) = zones->nodelist[i*shapesize+j];
}
DBFreeUcdmesh( mesh );
}
template<class TYPE>
void writeTriMeshVariable( DBfile* fid, int ndim, const std::string& meshname,
const std::string& varname, const Array<TYPE>& data, VariableType type )
{
int nvars = 0;
int vartype = 0;
const TYPE *vars[10] = { nullptr };
if ( type == VariableType::NodeVariable ) {
vartype = DB_NODECENT;
nvars = data.size(1);
for (int i=0; i<nvars; i++)
vars[i] = &data(0,i);
} else if ( type == VariableType::EdgeVariable ) {
ERROR("Not finished");
} else if ( type == VariableType::SurfaceVariable ) {
ERROR("Not finished");
} else if ( type == VariableType::VolumeVariable ) {
vartype = DB_ZONECENT;
nvars = data.size(1);
for (int i=0; i<nvars; i++)
vars[i] = &data(0,i);
} else {
ERROR("Invalid variable type");
}
auto suffix = getVarSuffix( ndim, nvars );
std::vector<std::string> var_names(nvars);
for (int i=0; i<nvars; i++)
var_names[i] = varname + suffix[i];
std::vector<char*> varnames(nvars,nullptr);
for (int i=0; i<nvars; i++)
varnames[i] = const_cast<char*>(var_names[i].c_str());
DBPutUcdvar( fid, varname.c_str(), meshname.c_str(), nvars,
varnames.data(), vars, data.size(0), nullptr, 0, getType<TYPE>(), vartype, nullptr );
}
template<class TYPE>
Array<TYPE> readTriMeshVariable( DBfile* fid, const std::string& varname )
{
auto var = DBGetUcdvar( fid, varname.c_str() );
ASSERT( var != nullptr );
Array<TYPE> data( var->nels, var->nvals );
int type = var->datatype;
for (int i=0; i<var->nvals; i++) {
Array<TYPE> data2( var->nels );
copyData<TYPE>( data2, type, var->vals[i] );
memcpy( &data(0,i), data2.data(), var->nels*sizeof(TYPE) );
}
DBFreeUcdvar( var );
return data;
}
/****************************************************
* Write a multimesh *
****************************************************/
@ -460,44 +103,10 @@ void writeMultiVar( DBfile* fid, const std::string& varname,
}
}; // silo namespace
// Explicit instantiations
template std::vector<int> silo::read<int>( DBfile* fid, const std::string& varname );
template std::vector<float> silo::read<float>( DBfile* fid, const std::string& varname );
template std::vector<double> silo::read<double>( DBfile* fid, const std::string& varname );
template void silo::writeUniformMesh<1>( DBfile*, const std::string&, const std::array<double,2>&, const std::array<int,1>& );
template void silo::writeUniformMesh<2>( DBfile*, const std::string&, const std::array<double,4>&, const std::array<int,2>& );
template void silo::writeUniformMesh<3>( DBfile*, const std::string&, const std::array<double,6>&, const std::array<int,3>& );
namespace {
template<class TYPE>
static void siloClassInstantiator() {
// use **all** functions here so that they get instantiated
const auto type = silo::VariableType::NullVariable;
Array<TYPE> tmp;
Array<int> tri;
silo::write<TYPE>( nullptr, "", std::vector<TYPE>() );
silo::read<TYPE>( nullptr, "" );
silo::writeUniformMeshVariable<1,TYPE>( nullptr, "", std::array<int,1>(), "", Array<TYPE>(), type );
silo::writeUniformMeshVariable<2,TYPE>( nullptr, "", std::array<int,2>(), "", Array<TYPE>(), type );
silo::writeUniformMeshVariable<3,TYPE>( nullptr, "", std::array<int,3>(), "", Array<TYPE>(), type );
silo::writePointMesh( nullptr, "", 0, 0, (const TYPE**) nullptr );
silo::writePointMeshVariable<TYPE>( nullptr, "", "", Array<TYPE>() );
silo::writeTriMesh<TYPE>( nullptr, "", 0, 0, 0, (const TYPE**) nullptr, 0, (const int**) nullptr );
silo::writeTriMeshVariable<TYPE>( nullptr, 0, "", "", Array<TYPE>(), type );
silo::readUniformMeshVariable<TYPE>( nullptr, "" );
silo::readPointMesh<TYPE>( nullptr, "" );
silo::readPointMeshVariable<TYPE>( nullptr, "" );
silo::readTriMesh<TYPE>( nullptr, "", tmp, tri );
silo::readTriMeshVariable<TYPE>( nullptr, "" );
};
template void siloClassInstantiator<double>();
template void siloClassInstantiator<float>();
template void siloClassInstantiator<int>();
}
#else
#endif

8
IO/silo.h
View File

@ -1,5 +1,5 @@
#ifndef NETCDF_READER
#define NETCDF_READER
#ifndef SILO_INTERFACE
#define SILO_INTERFACE
#include <string>
#include <vector>
@ -259,5 +259,9 @@ void writeMultiVar( DBfile* fid, const std::string& varname,
const std::vector<std::string>& subVarNames,
const std::vector<int>& subVarTypes );
}; // silo namespace
#endif
#include "IO/silo.hpp"

392
IO/silo.hpp Normal file
View File

@ -0,0 +1,392 @@
#ifndef SILO_INTERFACE_HPP
#define SILO_INTERFACE_HPP
#include "IO/silo.h"
#include "common/Utilities.h"
#include "common/MPI_Helpers.h"
#include "ProfilerApp.h"
#ifdef USE_SILO
#include <silo.h>
namespace silo {
/****************************************************
* Helper functions *
****************************************************/
template<class TYPE> static constexpr int getType();
template<> constexpr int getType<double>() { return DB_DOUBLE; }
template<> constexpr int getType<float>() { return DB_FLOAT; }
template<> constexpr int getType<int>() { return DB_INT; }
template<class TYPE>
inline void copyData( Array<TYPE>& data, int type, const void *src )
{
if ( type == getType<TYPE>() )
memcpy( data.data(), src, data.length()*sizeof(TYPE) );
else if ( type == DB_DOUBLE )
data.copy<double>( static_cast<const double*>(src) );
else if ( type == DB_FLOAT )
data.copy<float>( static_cast<const float*>(src) );
else if ( type == DB_INT )
data.copy<int>( static_cast<const int*>(src) );
else
ERROR("Unknown type");
}
/****************************************************
* Write/read an arbitrary vector *
****************************************************/
template<class TYPE> constexpr int getSiloType();
template<> constexpr int getSiloType<int>() { return DB_INT; }
template<> constexpr int getSiloType<float>() { return DB_FLOAT; }
template<> constexpr int getSiloType<double>() { return DB_DOUBLE; }
template<class TYPE>
void write( DBfile* fid, const std::string& varname, const std::vector<TYPE>& data )
{
int dims = data.size();
int err = DBWrite( fid, varname.c_str(), (void*) data.data(), &dims, 1, getSiloType<TYPE>() );
ASSERT( err == 0 );
}
template<class TYPE>
std::vector<TYPE> read( DBfile* fid, const std::string& varname )
{
int N = DBGetVarLength( fid, varname.c_str() );
std::vector<TYPE> data(N);
int err = DBReadVar( fid, varname.c_str(), data.data() );
ASSERT( err == 0 );
return data;
}
/****************************************************
* Helper function to get variable suffixes *
****************************************************/
inline std::vector<std::string> getVarSuffix( int ndim, int nvars )
{
std::vector<std::string> suffix(nvars);
if ( nvars == 1 ) {
suffix[0] = "";
} else if ( nvars == ndim ) {
if ( ndim==2 ) {
suffix[0] = "_x";
suffix[1] = "_y";
} else if ( ndim==3 ) {
suffix[0] = "_x";
suffix[1] = "_y";
suffix[2] = "_z";
} else {
ERROR("Not finished");
}
} else if ( nvars == ndim*ndim ) {
if ( ndim==2 ) {
suffix[0] = "_xx";
suffix[1] = "_xy";
suffix[2] = "_yx";
suffix[3] = "_yy";
} else if ( ndim==3 ) {
suffix[0] = "_xx";
suffix[1] = "_xy";
suffix[2] = "_xz";
suffix[3] = "_yx";
suffix[4] = "_yy";
suffix[5] = "_yz";
suffix[6] = "_zx";
suffix[7] = "_zy";
suffix[8] = "_zz";
} else {
ERROR("Not finished");
}
} else {
for (int i=0; i<nvars; i++)
suffix[i] = "_" + std::to_string(i+1);
}
return suffix;
}
/****************************************************
* Write/read a uniform mesh to silo *
****************************************************/
template<int NDIM>
void writeUniformMesh( DBfile* fid, const std::string& meshname,
const std::array<double,2*NDIM>& range, const std::array<int,NDIM>& N )
{
PROFILE_START("writeUniformMesh",2);
int dims[NDIM];
for (size_t d=0; d<N.size(); d++)
dims[d] = N[d]+1;
float *x = nullptr;
if ( NDIM >= 1 ) {
x = new float[dims[0]];
for (int i=0; i<N[0]; i++)
x[i] = range[0] + i*(range[1]-range[0])/N[0];
x[N[0]] = range[1];
}
float *y = nullptr;
if ( NDIM >= 2 ) {
y = new float[dims[1]];
for (int i=0; i<N[1]; i++)
y[i] = range[2] + i*(range[3]-range[2])/N[1];
y[N[1]] = range[3];
}
float *z = nullptr;
if ( NDIM >= 3 ) {
z = new float[dims[2]];
for (int i=0; i<N[2]; i++)
z[i] = range[4] + i*(range[5]-range[4])/N[2];
z[N[2]] = range[5];
}
float *coords[] = { x, y, z };
int err = DBPutQuadmesh( fid, meshname.c_str(), nullptr, coords, dims, NDIM, DB_FLOAT, DB_COLLINEAR, nullptr );
ASSERT( err == 0 );
PROFILE_STOP("writeUniformMesh",2);
}
/****************************************************
* Write a vector/tensor quad variable *
****************************************************/
template<int NDIM,class TYPE>
void writeUniformMeshVariable( DBfile* fid, const std::string& meshname, const std::array<int,NDIM>& N,
const std::string& varname, const Array<TYPE>& data, VariableType type )
{
PROFILE_START("writeUniformMeshVariable",2);
int nvars=1, dims[NDIM]={1};
const TYPE *vars[NDIM] = { nullptr };
int vartype = 0;
if ( type == VariableType::NodeVariable ) {
ASSERT( data.ndim()==NDIM || data.ndim()==NDIM+1 );
for (int d=0; d<NDIM; d++)
ASSERT(N[d]+1==(int)data.size(d));
vartype = DB_NODECENT;
nvars = data.size(NDIM);
size_t N = data.length()/nvars;
for (int d=0; d<NDIM; d++)
dims[d] = data.size(d);
for (int i=0; i<nvars; i++)
vars[i] = &data(i*N);
} else if ( type == VariableType::EdgeVariable ) {
ERROR("Not finished");
} else if ( type == VariableType::SurfaceVariable ) {
ERROR("Not finished");
} else if ( type == VariableType::VolumeVariable ) {
ASSERT( data.ndim()==NDIM || data.ndim()==NDIM+1 );
for (int d=0; d<NDIM; d++)
ASSERT(N[d]==(int)data.size(d));
vartype = DB_ZONECENT;
nvars = data.size(NDIM);
size_t N = data.length()/nvars;
for (int d=0; d<NDIM; d++)
dims[d] = data.size(d);
for (int i=0; i<nvars; i++)
vars[i] = &data(i*N);
} else {
ERROR("Invalid variable type");
}
auto suffix = getVarSuffix( NDIM, nvars );
std::vector<std::string> var_names(nvars);
for (int i=0; i<nvars; i++)
var_names[i] = varname + suffix[i];
std::vector<char*> varnames(nvars,nullptr);
for (int i=0; i<nvars; i++)
varnames[i] = const_cast<char*>(var_names[i].c_str());
int err = DBPutQuadvar( fid, varname.c_str(), meshname.c_str(), nvars,
varnames.data(), vars, dims, NDIM, nullptr, 0, getType<TYPE>(), vartype, nullptr );
ASSERT( err == 0 );
PROFILE_STOP("writeUniformMeshVariable",2);
}
template<class TYPE>
Array<TYPE> readUniformMeshVariable( DBfile* fid, const std::string& varname )
{
auto var = DBGetQuadvar( fid, varname.c_str() );
ASSERT( var != nullptr );
Array<TYPE> data( var->nels, var->nvals );
int type = var->datatype;
for (int i=0; i<var->nvals; i++) {
Array<TYPE> data2( var->nels );
copyData<TYPE>( data2, type, var->vals[i] );
memcpy( &data(0,i), data2.data(), var->nels*sizeof(TYPE) );
}
DBFreeQuadvar( var );
std::vector<size_t> dims( var->ndims+1, var->nvals );
for (int d=0; d<var->ndims; d++)
dims[d] = var->dims[d];
data.reshape( dims );
return data;
}
/****************************************************
* Read/write a point mesh/variable to silo *
****************************************************/
template<class TYPE>
void writePointMesh( DBfile* fid, const std::string& meshname,
int ndim, int N, const TYPE *coords[] )
{
int err = DBPutPointmesh( fid, meshname.c_str(), ndim, coords, N, getType<TYPE>(), nullptr );
ASSERT( err == 0 );
}
template<class TYPE>
Array<TYPE> readPointMesh( DBfile* fid, const std::string& meshname )
{
auto mesh = DBGetPointmesh( fid, meshname.c_str() );
int N = mesh->nels;
int ndim = mesh->ndims;
Array<TYPE> coords(N,ndim);
int type = mesh->datatype;
for (int d=0; d<ndim; d++) {
Array<TYPE> data2( N );
copyData<TYPE>( data2, type, mesh->coords[d] );
memcpy( &coords(0,d), data2.data(), N*sizeof(TYPE) );
}
DBFreePointmesh( mesh );
return coords;
}
template<class TYPE>
void writePointMeshVariable( DBfile* fid, const std::string& meshname,
const std::string& varname, const Array<TYPE>& data )
{
int N = data.size(0);
int nvars = data.size(1);
std::vector<const TYPE*> vars(nvars);
for (int i=0; i<nvars; i++)
vars[i] = &data(0,i);
int err = DBPutPointvar( fid, varname.c_str(), meshname.c_str(), nvars, vars.data(), N, getType<TYPE>(), nullptr );
ASSERT( err == 0 );
}
template<class TYPE>
Array<TYPE> readPointMeshVariable( DBfile* fid, const std::string& varname )
{
auto var = DBGetPointvar( fid, varname.c_str() );
ASSERT( var != nullptr );
Array<TYPE> data( var->nels, var->nvals );
int type = var->datatype;
for (int i=0; i<var->nvals; i++) {
Array<TYPE> data2( var->nels );
copyData<TYPE>( data2, type, var->vals[i] );
memcpy( &data(0,i), data2.data(), var->nels*sizeof(TYPE) );
}
DBFreeMeshvar( var );
return data;
}
/****************************************************
* Read/write a triangle mesh *
****************************************************/
template<class TYPE>
void writeTriMesh( DBfile* fid, const std::string& meshName,
int ndim, int ndim_tri, int N, const TYPE *coords[], int N_tri, const int *tri[] )
{
auto zoneName = meshName + "_zones";
std::vector<int> nodelist( (ndim_tri+1)*N_tri );
for (int i=0, j=0; i<N_tri; i++) {
for (int d=0; d<ndim_tri+1; d++, j++)
nodelist[j] = tri[d][i];
}
int shapetype = 0;
if ( ndim_tri==1 )
shapetype = DB_ZONETYPE_BEAM;
else if ( ndim_tri==2 )
shapetype = DB_ZONETYPE_TRIANGLE;
else if ( ndim_tri==3 )
shapetype = DB_ZONETYPE_PYRAMID;
else
ERROR("Unknown shapetype");
int shapesize = ndim_tri+1;
int shapecnt = N_tri;
DBPutZonelist2( fid, zoneName.c_str(), N_tri, ndim_tri, nodelist.data(),
nodelist.size(), 0, 0, 0, &shapetype, &shapesize, &shapecnt, 1, nullptr );
DBPutUcdmesh( fid, meshName.c_str(), ndim, nullptr, coords, N,
nodelist.size(), zoneName.c_str(), nullptr, getType<TYPE>(), nullptr );
}
template<class TYPE>
void readTriMesh( DBfile* fid, const std::string& meshname, Array<TYPE>& coords, Array<int>& tri )
{
auto mesh = DBGetUcdmesh( fid, meshname.c_str() );
int ndim = mesh->ndims;
int N_nodes = mesh->nnodes;
coords.resize(N_nodes,ndim);
int mesh_type = mesh->datatype;
for (int d=0; d<ndim; d++) {
Array<TYPE> data2( N_nodes );
copyData<TYPE>( data2, mesh_type, mesh->coords[d] );
memcpy( &coords(0,d), data2.data(), N_nodes*sizeof(TYPE) );
}
auto zones = mesh->zones;
int N_zones = zones->nzones;
int ndim_zones = zones->ndims;
ASSERT( zones->nshapes==1 );
int shape_type = zones->shapetype[0];
int shapesize = zones->shapesize[0];
tri.resize(N_zones,shapesize);
for (int i=0; i<N_zones; i++) {
for (int j=0; j<shapesize; j++)
tri(i,j) = zones->nodelist[i*shapesize+j];
}
DBFreeUcdmesh( mesh );
}
template<class TYPE>
void writeTriMeshVariable( DBfile* fid, int ndim, const std::string& meshname,
const std::string& varname, const Array<TYPE>& data, VariableType type )
{
int nvars = 0;
int vartype = 0;
const TYPE *vars[10] = { nullptr };
if ( type == VariableType::NodeVariable ) {
vartype = DB_NODECENT;
nvars = data.size(1);
for (int i=0; i<nvars; i++)
vars[i] = &data(0,i);
} else if ( type == VariableType::EdgeVariable ) {
ERROR("Not finished");
} else if ( type == VariableType::SurfaceVariable ) {
ERROR("Not finished");
} else if ( type == VariableType::VolumeVariable ) {
vartype = DB_ZONECENT;
nvars = data.size(1);
for (int i=0; i<nvars; i++)
vars[i] = &data(0,i);
} else {
ERROR("Invalid variable type");
}
auto suffix = getVarSuffix( ndim, nvars );
std::vector<std::string> var_names(nvars);
for (int i=0; i<nvars; i++)
var_names[i] = varname + suffix[i];
std::vector<char*> varnames(nvars,nullptr);
for (int i=0; i<nvars; i++)
varnames[i] = const_cast<char*>(var_names[i].c_str());
DBPutUcdvar( fid, varname.c_str(), meshname.c_str(), nvars,
varnames.data(), vars, data.size(0), nullptr, 0, getType<TYPE>(), vartype, nullptr );
}
template<class TYPE>
Array<TYPE> readTriMeshVariable( DBfile* fid, const std::string& varname )
{
auto var = DBGetUcdvar( fid, varname.c_str() );
ASSERT( var != nullptr );
Array<TYPE> data( var->nels, var->nvals );
int type = var->datatype;
for (int i=0; i<var->nvals; i++) {
Array<TYPE> data2( var->nels );
copyData<TYPE>( data2, type, var->vals[i] );
memcpy( &data(0,i), data2.data(), var->nels*sizeof(TYPE) );
}
DBFreeUcdvar( var );
return data;
}
}; // silo namespace
#endif
#endif