Simbody
3.5
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The purpose of the CNT<T> class is to hide the differences between built-in numerical types and composite ones like Vec<3>. More...
Go to the source code of this file.
Classes | |
singleton | SimTK::CNT< K > |
Specialized information about Composite Numerical Types which allows us to define appropriate templatized classes using them. More... | |
struct | SimTK::CNT< K >::Result< P > |
struct | SimTK::CNT< K >::Substitute< P > |
Namespaces | |
SimTK | |
This is the top-level SimTK namespace into which all SimTK names are placed to avoid collision with other symbols. | |
Enumerations | |
enum | { SimTK::SCALAR_DEPTH = 0, SimTK::SCALAR_COMPOSITE_DEPTH = 1, SimTK::COMPOSITE_COMPOSITE_DEPTH = 2, SimTK::COMPOSITE_3_DEPTH = 3, SimTK::MAX_RESOLVED_DEPTH = COMPOSITE_3_DEPTH } |
The purpose of the CNT<T> class is to hide the differences between built-in numerical types and composite ones like Vec<3>.
We can decorate all the composite types with whatever information we need, but we cannot add to the built-in types in the same way. So we define a templatized class CNT<T>, where the template parameter can be any composite numerical type whether built in or composite. Then CNT members are used to access information about class T. When T is a built-in, that information comes from specializations of CNT<T> for CNT<float>, CNT<std::complex<double>>, etc. When T is composite, CNT<T> acts as a pass-through to allow the composite type to provide its own information.
Here is the information that must be provided by a SimTK Composite Numerical Type T (or faked up for built-ins). Some of these are given friendly names and documented since they are useful in user code.
Type Meaning ---------------- --------------------------------------------------------
TNeg same shape as T, but elements are negated TReal same shape as T, but with real elements TImag same shape as T, with real elements from imaginary part TComplex same shape as T, but with Complex or conjugate elements THerm transpose of T, with Hermitian transposed elements TPosTrans positional transpose of T; i.e., elements not transposed TSqHermT type of ~T*T (default vector & matrix square; symmetric) TSqTHerm type of T*~T (row square; symmetric)
Scalar the underlying scalar type (see below) ScalarNormSq type of the "conjugate square" ~s*s of underlying scalar (always real)
Substitute<E>::Type A CNT of the same shape and container type as this one, but with elements of type E instead of ElementType. Special case: if this CNT is a scalar then Substitute<E>::Type just returns E. Result<RHS>::Mul (Dvd,Add,Sub) The type of the result of T op RHS, where RHS is *any* CNT
ENUMS (all sizes are in units of T's elements)
NRows logical num rows in type T (i.e., num elements in a column) NCols logical number of columns in type T RowSpacing num elements from one row to the next (default 1) ColSpacing num elements from one col to the next (default NRows for Mat) NPackedElements minimum num elements it would take to store this data NActualElements num elements covered by T due to element spacing NActualScalars NActualElements * CNT<ElementType>::NActualScalars. This should be the physical spacing between array elements in an array containing this kind of CNT. Our big Matrix/Vector types guarantee this packing.
* * The Scalar Types * ---------------- * Here is a complete taxonomy of the scalar types we support. * * <scalar> ::= quantity< unitType, <unitlessScalar> > * <unitlessScalar> ::= <number> | negator< <number> > * <number> ::= <standard> | <conjugate> * <standard> ::= <real> | <complex> * * <real> ::= float | double | long double * <complex> ::= std::complex< <real> > * <conjugate> ::= SimTK::conjugate< <real> > * *
With this in hand, we can build a clean facility in which scalars, vectors, matrices, vectors of vectors, matrices of vectors of matrices, etc. can all be treated uniformly.