eigen3-hdf5/eigen3-hdf5.hpp

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2019-08-10 09:41:30 +00:00
#ifndef EIGEN3_HDF5_HPP_
#define EIGEN3_HDF5_HPP_
#include <cassert>
#include <complex>
#include <cstddef>
#include <stdexcept>
#include <string>
#include <vector>
#include <H5Cpp.h>
#include <H5public.h>
#include <Eigen/Dense>
#if H5_VERSION_LE( 1, 10, 0 )
// typedef H5::H5Location Eigen3Hdf5_H5Location;
// typedef H5::CommonFG Eigen3Hdf5_H5CommonFG;
#define Eigen3Hdf5_H5Location H5::H5Location
#define Eigen3Hdf5_H5CommonFG H5::CommonFG
#else
// typedef H5::H5Object Eigen3Hdf5_H5Location;
// typedef H5::H5Object Eigen3Hdf5_H5CommonFG;
#define Eigen3Hdf5_H5Location H5::H5Object
#define Eigen3Hdf5_H5CommonFG H5::H5Object
#endif
namespace Eigen3HDF5
{
template <typename T>
struct DatatypeSpecialization;
// floating-point types
template <>
struct DatatypeSpecialization<float>
{
static inline const H5::DataType* get( void )
{
return( &H5::PredType::NATIVE_FLOAT );
}
};
template <>
struct DatatypeSpecialization<double>
{
static inline const H5::DataType* get( void )
{
return( &H5::PredType::NATIVE_DOUBLE );
}
};
template <>
struct DatatypeSpecialization<long double>
{
static inline const H5::DataType* get( void )
{
return( &H5::PredType::NATIVE_LDOUBLE );
}
};
// integer types
template <>
struct DatatypeSpecialization<short>
{
static inline const H5::DataType* get( void )
{
return( &H5::PredType::NATIVE_SHORT );
}
};
template <>
struct DatatypeSpecialization<unsigned short>
{
static inline const H5::DataType* get( void )
{
return( &H5::PredType::NATIVE_USHORT );
}
};
template <>
struct DatatypeSpecialization<int>
{
static inline const H5::DataType* get( void )
{
return( &H5::PredType::NATIVE_INT );
}
};
template <>
struct DatatypeSpecialization<unsigned int>
{
static inline const H5::DataType* get( void )
{
return( &H5::PredType::NATIVE_UINT );
}
};
template <>
struct DatatypeSpecialization<long>
{
static inline const H5::DataType* get( void )
{
return( &H5::PredType::NATIVE_LONG );
}
};
template <>
struct DatatypeSpecialization<unsigned long>
{
static inline const H5::DataType* get( void )
{
return( &H5::PredType::NATIVE_ULONG );
}
};
template <>
struct DatatypeSpecialization<long long>
{
static inline const H5::DataType* get( void )
{
return( &H5::PredType::NATIVE_LLONG );
}
};
template <>
struct DatatypeSpecialization<unsigned long long>
{
static inline const H5::DataType* get( void )
{
return( &H5::PredType::NATIVE_ULLONG );
}
};
// complex types
//
// inspired by http://www.mail-archive.com/hdf-forum@hdfgroup.org/msg00759.html
template <typename T>
class ComplexH5Type : public H5::CompType
{
public:
ComplexH5Type ( void )
: CompType( sizeof( std::complex<T> ) )
{
const H5::DataType* const datatype = DatatypeSpecialization<T>::get();
assert( datatype->getSize() == sizeof( T ) );
// If we call the members "r" and "i", h5py interprets the
// structure correctly as complex numbers.
this->insertMember( std::string( "r" ), 0, *datatype );
this->insertMember( std::string( "i" ), sizeof( T ), *datatype );
this->pack();
}
static const ComplexH5Type<T>* get_singleton( void )
{
// NOTE: constructing this could be a race condition
static ComplexH5Type<T> singleton;
return( &singleton );
}
};
template <typename T>
struct DatatypeSpecialization<std::complex<T> >
{
static inline const H5::DataType* get( void )
{
return( ComplexH5Type<T>::get_singleton() );
}
};
// string types, to be used mainly for attributes
template <>
struct DatatypeSpecialization<const char*>
{
static inline const H5::DataType* get( void )
{
static const H5::StrType strtype( 0, H5T_VARIABLE );
return( &strtype );
}
};
template <>
struct DatatypeSpecialization<char*>
{
static inline const H5::DataType* get( void )
{
static const H5::StrType strtype( 0, H5T_VARIABLE );
return( &strtype );
}
};
// XXX: for some unknown reason the following two functions segfault if
// H5T_VARIABLE is used. The passed strings should still be null-terminated,
// so this is a bit worrisome.
template <std::size_t N>
struct DatatypeSpecialization<const char [N]>
{
static inline const H5::DataType* get( void )
{
static const H5::StrType strtype( 0, N );
return( &strtype );
}
};
template <std::size_t N>
struct DatatypeSpecialization<char [N]>
{
static inline const H5::DataType* get( void )
{
static const H5::StrType strtype( 0, N );
return( &strtype );
}
};
namespace internal
{
template <typename Derived>
H5::DataSpace create_dataspace( const Eigen::EigenBase<Derived>& mat )
{
const std::size_t dimensions_size = 2;
const hsize_t dimensions[dimensions_size] = {
static_cast<hsize_t>( mat.rows() ),
static_cast<hsize_t>( mat.cols() )
};
return( H5::DataSpace( dimensions_size, dimensions ) );
}
template <typename Derived>
bool write_rowmat( const Eigen::EigenBase<Derived>& mat,
const H5::DataType* const datatype,
H5::DataSet* dataset,
const H5::DataSpace* dspace )
{
if ( mat.derived().innerStride() != 1 )
{
// inner stride != 1 is an edge case this function does not (yet) handle. (I think it
// could by using the inner stride as the first element of mstride below. But I do
// not have a test case to try it out, so just return false for now.)
return( false );
}
assert( mat.rows() >= 0 );
assert( mat.cols() >= 0 );
assert( mat.derived().outerStride() >= 0 );
hsize_t rows = hsize_t( mat.rows() );
hsize_t cols = hsize_t( mat.cols() );
hsize_t stride = hsize_t( mat.derived().outerStride() );
// slab params for the file data
hsize_t fstride[2] = { 1, cols };
// slab params for the memory data
hsize_t mstride[2] = { 1, stride };
// slab params for both file and memory data
hsize_t count[2] = { 1, 1 };
hsize_t block[2] = { rows, cols };
hsize_t start[2] = { 0, 0 };
// memory dataspace
hsize_t mdim[2] = { rows, stride };
H5::DataSpace mspace( 2, mdim );
dspace->selectHyperslab( H5S_SELECT_SET, count, start, fstride, block );
mspace.selectHyperslab( H5S_SELECT_SET, count, start, mstride, block );
dataset->write( mat.derived().data(), *datatype, mspace, *dspace );
return( true );
}
template <typename Derived>
bool write_colmat( const Eigen::EigenBase<Derived>& mat,
const H5::DataType* const datatype,
H5::DataSet* dataset,
const H5::DataSpace* dspace )
{
if ( mat.derived().innerStride() != 1 )
{
// inner stride != 1 is an edge case this function does not (yet) handle. (I think it
// could by using the inner stride as the first element of mstride below. But I do
// not have a test case to try it out, so just return false for now.)
return( false );
}
assert( mat.rows() >= 0 );
assert( mat.cols() >= 0 );
assert( mat.derived().outerStride() >= 0 );
hsize_t rows = hsize_t( mat.rows() );
hsize_t cols = hsize_t( mat.cols() );
hsize_t stride = hsize_t( mat.derived().outerStride() );
// slab params for the file data
hsize_t fstride[2] = { 1, cols };
hsize_t fcount[2] = { 1, 1 };
hsize_t fblock[2] = { 1, cols };
// slab params for the memory data
hsize_t mstride[2] = { stride, 1 };
hsize_t mcount[2] = { 1, 1 };
hsize_t mblock[2] = { cols, 1 };
// memory dataspace
hsize_t mdim[2] = { cols, stride };
H5::DataSpace mspace( 2, mdim );
// transpose the column major data in memory to the row major data in the file by
// writing one row slab at a time.
for ( hsize_t i = 0; i < rows; i++ )
{
hsize_t fstart[2] = { i, 0 };
hsize_t mstart[2] = { 0, i };
dspace->selectHyperslab( H5S_SELECT_SET, fcount, fstart, fstride, fblock );
mspace.selectHyperslab( H5S_SELECT_SET, mcount, mstart, mstride, mblock );
dataset->write( mat.derived().data(), *datatype, mspace, *dspace );
}
return( true );
}
}
template <typename T>
void save_scalar_attribute( const Eigen3Hdf5_H5Location& h5obj, const std::string& name, const T& value )
{
const H5::DataType* const datatype = DatatypeSpecialization<T>::get();
H5::DataSpace dataspace( H5S_SCALAR );
H5::Attribute att = h5obj.createAttribute( name, *datatype, dataspace );
att.write( *datatype, &value );
}
template <>
inline void save_scalar_attribute( const Eigen3Hdf5_H5Location& h5obj, const std::string& name, const std::string& value )
{
save_scalar_attribute( h5obj, name, value.c_str() );
}
// see http://eigen.tuxfamily.org/dox/TopicFunctionTakingEigenTypes.html
template <typename Derived>
void save( Eigen3Hdf5_H5CommonFG& h5group, const std::string& name, const Eigen::EigenBase<Derived>& mat, const H5::DSetCreatPropList& plist = H5::DSetCreatPropList::DEFAULT )
{
typedef typename Derived::Scalar Scalar;
const H5::DataType* const datatype = DatatypeSpecialization<Scalar>::get();
const H5::DataSpace dataspace = internal::create_dataspace( mat );
H5::DataSet dataset = h5group.createDataSet( name, *datatype, dataspace, plist );
bool written = false; // flag will be true when the data has been written
if ( mat.derived().Flags & Eigen::RowMajor )
{
written = internal::write_rowmat( mat, datatype, &dataset, &dataspace );
}
else
{
written = internal::write_colmat( mat, datatype, &dataset, &dataspace );
}
if ( !written )
{
// data has not yet been written, so there is nothing else to try but copy the input
// matrix to a row major matrix and write it.
const Eigen::Matrix<Scalar, Eigen::Dynamic, Eigen::Dynamic, Eigen::RowMajor> row_major_mat( mat );
dataset.write( row_major_mat.data(), *datatype );
}
}
template <typename Derived>
void save_attribute( const Eigen3Hdf5_H5Location& h5obj, const std::string& name, const Eigen::EigenBase<Derived>& mat )
{
typedef typename Derived::Scalar Scalar;
const Eigen::Matrix<Scalar, Eigen::Dynamic, Eigen::Dynamic, Eigen::RowMajor> row_major_mat( mat );
const H5::DataSpace dataspace = internal::create_dataspace( mat );
const H5::DataType* const datatype = DatatypeSpecialization<Scalar>::get();
H5::Attribute dataset = h5obj.createAttribute( name, *datatype, dataspace );
dataset.write( *datatype, row_major_mat.data() );
}
namespace internal
{
// H5::Attribute and H5::DataSet both have similar API's, and although they
// share a common base class, the relevant methods are not virtual. Worst
// of all, they take their arguments in different orders!
template <typename Scalar>
inline void read_data( const H5::DataSet& dataset, Scalar* data, const H5::DataType& datatype )
{
dataset.read( data, datatype );
}
template <typename Scalar>
inline void read_data( const H5::Attribute& dataset, Scalar* data, const H5::DataType& datatype )
{
dataset.read( datatype, data );
}
// read a column major attribute; I do not know if there is an hdf routine to read an
// attribute hyperslab, so I take the lazy way out: just read the conventional hdf
// row major data and let eigen copy it into mat.
template <typename Derived>
bool read_colmat( const Eigen::DenseBase<Derived>& mat,
const H5::DataType* const datatype,
const H5::Attribute& dataset )
{
typename Derived::Index rows = mat.rows();
typename Derived::Index cols = mat.cols();
typename Eigen::Matrix<typename Derived::Scalar, Eigen::Dynamic, Eigen::Dynamic, Eigen::RowMajor> temp( rows, cols );
internal::read_data( dataset, temp.data(), *datatype );
const_cast<Eigen::DenseBase<Derived>&>( mat ) = temp;
return( true );
}
template <typename Derived>
bool read_colmat( const Eigen::DenseBase<Derived>& mat,
const H5::DataType* const datatype,
const H5::DataSet& dataset )
{
if ( mat.derived().innerStride() != 1 )
{
// inner stride != 1 is an edge case this function does not (yet) handle. (I think it
// could by using the inner stride as the first element of mstride below. But I do
// not have a test case to try it out, so just return false for now.)
return( false );
}
assert( mat.rows() >= 0 );
assert( mat.cols() >= 0 );
assert( mat.derived().outerStride() >= 0 );
hsize_t rows = hsize_t( mat.rows() );
hsize_t cols = hsize_t( mat.cols() );
hsize_t stride = hsize_t( mat.derived().outerStride() );
if ( stride != rows )
{
// this function does not (yet) read into a mat that has a different stride than the
// dataset.
return( false );
}
// slab params for the file data
hsize_t fstride[2] = { 1, cols };
hsize_t fcount[2] = { 1, 1 };
hsize_t fblock[2] = { 1, cols };
// file dataspace
hsize_t fdim[2] = { rows, cols };
H5::DataSpace fspace( 2, fdim );
// slab params for the memory data
hsize_t mstride[2] = { stride, 1 };
hsize_t mcount[2] = { 1, 1 };
hsize_t mblock[2] = { cols, 1 };
// memory dataspace
hsize_t mdim[2] = { cols, stride };
H5::DataSpace mspace( 2, mdim );
// transpose the column major data in memory to the row major data in the file by
// writing one row slab at a time.
for ( hsize_t i = 0; i < rows; i++ )
{
hsize_t fstart[2] = { i, 0 };
hsize_t mstart[2] = { 0, i };
fspace.selectHyperslab( H5S_SELECT_SET, fcount, fstart, fstride, fblock );
mspace.selectHyperslab( H5S_SELECT_SET, mcount, mstart, mstride, mblock );
dataset.read( const_cast<Eigen::DenseBase<Derived>&>( mat ).derived().data(), *datatype, mspace, fspace );
}
return( true );
}
template <typename Derived, typename DataSet>
void _load( const DataSet& dataset, const Eigen::DenseBase<Derived>& mat )
{
typedef typename Derived::Scalar Scalar;
const H5::DataSpace dataspace = dataset.getSpace();
const std::size_t ndims = dataspace.getSimpleExtentNdims();
assert( ndims > 0 );
const std::size_t dimensions_size = 2;
hsize_t dimensions[dimensions_size];
dimensions[1] = 1; // in case it's 1D
if ( ndims > dimensions_size )
{
throw std::runtime_error( "HDF5 array has too many dimensions." );
}
dataspace.getSimpleExtentDims( dimensions );
const hsize_t rows = dimensions[0], cols = dimensions[1];
const H5::DataType* const datatype = DatatypeSpecialization<Scalar>::get();
Eigen::DenseBase<Derived>& mat_ = const_cast<Eigen::DenseBase<Derived>&>( mat );
mat_.derived().resize( rows, cols );
bool written = false;
bool isRowMajor = mat.Flags & Eigen::RowMajor;
if ( isRowMajor || ( dimensions[0] == 1 ) || ( dimensions[1] == 1 ) )
{
// mat is already row major
typename Derived::Index istride = mat_.derived().outerStride();
assert( istride >= 0 );
hsize_t stride = istride >= 0 ? istride : 0;
if ( ( stride == cols ) || ( ( stride == rows ) && ( cols == 1 ) ) )
{
// mat has natural stride, so read directly into its data block
read_data( dataset, mat_.derived().data(), *datatype );
written = true;
}
}
else
{
// colmajor flag is 0 so the assert needs to check that mat is not rowmajor.
assert( !( mat.Flags & Eigen::RowMajor ) );
written = read_colmat( mat_, datatype, dataset );
}
if ( !written )
{
// dataset has not been loaded directly into mat_, so as a last resort read it into a
// temp and copy it to mat_. (Should only need to do this when the mat_ to be loaded
// into has an unnatural stride.)
Eigen::Matrix<Scalar, Eigen::Dynamic, Eigen::Dynamic, Eigen::RowMajor> temp( rows, cols );
internal::read_data( dataset, temp.data(), *datatype );
mat_ = temp;
written = true;
}
}
}
template <typename Derived>
void load( const Eigen3Hdf5_H5CommonFG& h5group, const std::string& name, const Eigen::DenseBase<Derived>& mat )
{
const H5::DataSet dataset = h5group.openDataSet( name );
internal::_load( dataset, mat );
}
template <typename Derived>
void load_attribute( const Eigen3Hdf5_H5Location& h5obj, const std::string& name, const Eigen::DenseBase<Derived>& mat )
{
const H5::Attribute dataset = h5obj.openAttribute( name );
internal::_load( dataset, mat );
}
template <typename T>
void load_scalar_attribute( const Eigen3Hdf5_H5Location& h5obj, const std::string& name, T& value )
{
const H5::Attribute att = h5obj.openAttribute( name );
const H5::DataType* const datatype = DatatypeSpecialization<T>::get();
att.read( *datatype, &value );
}
void load_scalar_attribute( const Eigen3Hdf5_H5Location& h5obj, const std::string& name, std::string& value )
{
const H5::Attribute att = h5obj.openAttribute( name );
const H5::DataType* const datatype = DatatypeSpecialization<const char*>::get();
att.read( *datatype, value );
}
} // namespace Eigen3HDF5
#endif