ECCE @ EIC Software
Reference for
ECCE @ EIC
simulation and reconstruction software on GitHub
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A spline with Y transformed into log space.Most useful for functions looking like y=exp(x) More...
#include <geant4/tree/geant4-10.6-release/examples/extended/electromagnetic/TestEm7/include/c2_function.hh>
Public Member Functions | |
lin_log_interpolating_function_p () | |
an empty linear-log cubic-spline interpolating_function_p | |
virtual interpolating_function_p < float_type > & | clone () const |
Public Member Functions inherited from interpolating_function_p< float_type > | |
interpolating_function_p () | |
an empty linear-linear cubic-spline interpolating_function_p | |
interpolating_function_p (const c2_function_transformation< float_type > &transform) | |
an empty cubic-spline interpolating_function_p with a specific transform | |
interpolating_function_p < float_type > & | load (const std::vector< float_type > &x, const std::vector< float_type > &f, bool lowerSlopeNatural, float_type lowerSlope, bool upperSlopeNatural, float_type upperSlope, bool splined=true) |
do the dirty work of constructing the spline from a function. | |
interpolating_function_p < float_type > & | load_pairs (std::vector< std::pair< float_type, float_type > > &data, bool lowerSlopeNatural, float_type lowerSlope, bool upperSlopeNatural, float_type upperSlope, bool splined=true) |
do the dirty work of constructing the spline from a function. | |
interpolating_function_p < float_type > & | sample_function (const c2_function< float_type > &func, float_type amin, float_type amax, float_type abs_tol, float_type rel_tol, bool lowerSlopeNatural, float_type lowerSlope, bool upperSlopeNatural, float_type upperSlope) |
do the dirty work of constructing the spline from a function. | |
interpolating_function_p < float_type > & | load_random_generator_function (const std::vector< float_type > &bincenters, const c2_function< float_type > &binheights) |
initialize from a grid of points and a c2_function (un-normalized) to an interpolator which, when evaluated with a uniform random variate on [0,1] returns random numbers distributed as the input function. | |
interpolating_function_p < float_type > & | load_random_generator_bins (const std::vector< float_type > &bins, const std::vector< float_type > &binheights, bool splined=true) |
virtual float_type | value_with_derivatives (float_type x, float_type *yprime, float_type *yprime2) const |
get the value and derivatives. | |
virtual | ~interpolating_function_p () |
destructor | |
void | get_data (std::vector< float_type > &xvals, std::vector< float_type > &yvals) const |
void | get_internal_data (std::vector< float_type > &xvals, std::vector< float_type > &yvals, std::vector< float_type > &y2vals) const |
void | set_lower_extrapolation (float_type bound) |
void | set_upper_extrapolation (float_type bound) |
interpolating_function_p < float_type > & | unary_operator (const c2_function< float_type > &source) const |
interpolating_function_p < float_type > & | binary_operator (const c2_function< float_type > &rhs, const c2_binary_function< float_type > *combining_stub) const |
interpolating_function_p < float_type > & | add_pointwise (const c2_function< float_type > &rhs) const |
interpolating_function_p < float_type > & | subtract_pointwise (const c2_function< float_type > &rhs) const |
interpolating_function_p < float_type > & | multiply_pointwise (const c2_function< float_type > &rhs) const |
interpolating_function_p < float_type > & | divide_pointwise (const c2_function< float_type > &rhs) const |
void | clone_data (const interpolating_function_p< float_type > &rhs) |
Public Member Functions inherited from c2_function< float_type > | |
const std::string | cvs_header_vers () const |
get versioning information for the header file | |
const std::string | cvs_file_vers () const |
get versioning information for the source file | |
virtual | ~c2_function () |
destructor | |
float_type | operator() (float_type x) const |
evaluate the function in the classic way, ignoring derivatives. | |
float_type | operator() (float_type x, float_type *yprime, float_type *yprime2) const |
get the value and derivatives. | |
float_type | find_root (float_type lower_bracket, float_type upper_bracket, float_type start, float_type value, int *error=0, float_type *final_yprime=0, float_type *final_yprime2=0) const |
solve f(x)==value very efficiently, with explicit knowledge of derivatives of the function | |
float_type | partial_integrals (std::vector< float_type > xgrid, std::vector< float_type > *partials=0, float_type abs_tol=1e-12, float_type rel_tol=1e-12, int derivs=2, bool adapt=true, bool extrapolate=true) const |
float_type | integral (float_type amin, float_type amax, std::vector< float_type > *partials=0, float_type abs_tol=1e-12, float_type rel_tol=1e-12, int derivs=2, bool adapt=true, bool extrapolate=true) const |
a fully-automated integrator which uses the information provided by the get_sampling_grid() function to figure out what to do. | |
c2_piecewise_function_p < float_type > * | adaptively_sample (float_type amin, float_type amax, float_type abs_tol=1e-12, float_type rel_tol=1e-12, int derivs=2, std::vector< float_type > *xvals=0, std::vector< float_type > *yvals=0) const |
create a c2_piecewise_function_p from c2_connector_function_p segments which is a representation of the parent function to the specified accuracy, but maybe much cheaper to evaluate | |
float_type | xmin () const |
float_type | xmax () const |
void | set_domain (float_type amin, float_type amax) |
size_t | get_evaluations () const |
void | reset_evaluations () const |
reset the counter | |
void | increment_evaluations () const |
count evaluations | |
bool | check_monotonicity (const std::vector< float_type > &data, const char message[]) const |
check that a vector is monotonic, throw an exception if not, and return a flag if it is reversed | |
virtual void | set_sampling_grid (const std::vector< float_type > &grid) |
establish a grid of 'interesting' points on the function. | |
std::vector< float_type > * | get_sampling_grid_pointer () const |
get the sampling grid, which may be a null pointer | |
virtual void | get_sampling_grid (float_type amin, float_type amax, std::vector< float_type > &grid) const |
void | preen_sampling_grid (std::vector< float_type > *result) const |
The grid is modified in place. | |
void | refine_sampling_grid (std::vector< float_type > &grid, size_t refinement) const |
c2_function< float_type > & | normalized_function (float_type amin, float_type amax, float_type norm=1.0) const |
create a new c2_function from this one which is normalized on the interval | |
c2_function< float_type > & | square_normalized_function (float_type amin, float_type amax, float_type norm=1.0) const |
c2_function< float_type > & | square_normalized_function (float_type amin, float_type amax, const c2_function< float_type > &weight, float_type norm=1.0) const |
create a new c2_function from this one which is square-normalized with the provided weight on the interval | |
c2_sum_p< float_type > & | operator+ (const c2_function< float_type > &rhs) const |
factory function to create a c2_sum_p from a regular algebraic expression. | |
c2_diff_p< float_type > & | operator- (const c2_function< float_type > &rhs) const |
factory function to create a c2_diff_p from a regular algebraic expression. | |
c2_product_p< float_type > & | operator* (const c2_function< float_type > &rhs) const |
factory function to create a c2_product_p from a regular algebraic expression. | |
c2_ratio_p< float_type > & | operator/ (const c2_function< float_type > &rhs) const |
c2_composed_function_p < float_type > & | operator() (const c2_function< float_type > &inner) const |
compose this function outside another. | |
float_type | get_trouble_point () const |
Find out where a calculation ran into trouble, if it got a nan. If the most recent computation did not return a nan, this is undefined. | |
void | claim_ownership () const |
increment our reference count. Destruction is only legal if the count is zero. | |
size_t | release_ownership_for_return () const |
decrement our reference count. Do not destroy at zero. | |
void | release_ownership () const |
size_t | count_owners () const |
get the reference count, mostly for debugging | |
void | fill_fblock (c2_fblock< float_type > &fb) const |
fill in a c2_fblock<float_type>... a shortcut for the integrator & sampler | |
Additional Inherited Members | |
Public Attributes inherited from interpolating_function_p< float_type > | |
const c2_function_transformation < float_type > & | fTransform |
Protected Member Functions inherited from interpolating_function_p< float_type > | |
void | spline (bool lowerSlopeNatural, float_type lowerSlope, bool upperSlopeNatural, float_type upperSlope) |
create the spline coefficients | |
Static Protected Member Functions inherited from interpolating_function_p< float_type > | |
static bool | comp_pair (std::pair< float_type, float_type > const &i, std::pair< float_type, float_type > const &j) |
Protected Attributes inherited from interpolating_function_p< float_type > | |
std::vector< float_type > | Xraw |
std::vector< float_type > | X |
std::vector< float_type > | F |
std::vector< float_type > | y2 |
c2_const_ptr< float_type > | sampler_function |
bool | xInverted |
size_t | lastKLow |
A spline with Y transformed into log space.
Most useful for functions looking like y=exp(x)
Definition at line 1743 of file c2_function.hh.
View newest version in sPHENIX GitHub at line 1743 of file c2_function.hh
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inline |
an empty linear-log cubic-spline interpolating_function_p
Definition at line 1748 of file c2_function.hh.
View newest version in sPHENIX GitHub at line 1748 of file c2_function.hh
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inlinevirtual |
Reimplemented from interpolating_function_p< float_type >.
Definition at line 1752 of file c2_function.hh.
View newest version in sPHENIX GitHub at line 1752 of file c2_function.hh