basefunctor

class zfit.models.basefunctor.FunctorMixin(models, obs, **kwargs)[source]

Bases: zfit.core.interfaces.ZfitFunctorMixin, zfit.core.basemodel.BaseModel

add_cache_deps(cache_deps: Union[zfit.core.interfaces.ZfitCachable, Iterable[zfit.core.interfaces.ZfitCachable]], allow_non_cachable: bool = True)

Add dependencies that render the cache invalid if they change.

Parameters:
  • cache_deps (ZfitGraphCachable) –
  • allow_non_cachable (bool) – If True, allow cache_dependents to be non-cachables. If False, any cache_dependents that is not a ZfitCachable will raise an error.
Raises:

TypeError – if one of the cache_dependents is not a ZfitCachable _and_ allow_non_cachable if False.
analytic_integrate(limits: Union[Tuple[Tuple[float, ...]], Tuple[float, ...], bool], norm_range: Union[Tuple[Tuple[float, ...]], Tuple[float, ...], bool] = None) → Union[float, tensorflow.python.framework.ops.Tensor]

Analytical integration over function and raise Error if not possible.

Parameters:
  • limits (tuple, ZfitSpace) – the limits to integrate over
  • norm_range (tuple, ZfitSpace, False) – the limits to normalize over
Returns:

the integral value
Return type:

Tensor
Raises:
  • AnalyticIntegralNotImplementedError – If no analytical integral is available (for this limits).
  • NormRangeNotImplementedError – if the norm_range argument is not supported. This means that no analytical normalization is available, explicitly: the analytical integral over the limits = norm_range is not available.
axes

Return the axes, integer based identifier(indices) for the coordinate system.

convert_sort_space(obs: Union[str, Iterable[str], zfit.Space, zfit.core.interfaces.ZfitLimit, tensorflow.python.framework.ops.Tensor, numpy.ndarray, Iterable[float], float, Tuple[float], List[float], bool, None] = None, axes: Union[int, Iterable[int]] = None, limits: Union[zfit.core.interfaces.ZfitLimit, tensorflow.python.framework.ops.Tensor, numpy.ndarray, Iterable[float], float, Tuple[float], List[float], bool, None] = None) → Optional[zfit.core.interfaces.ZfitSpace]

Convert the inputs (using eventually obs, axes) to ZfitSpace and sort them according to own obs.

Parameters:
  • () (limits) –
  • ()
  • ()

Returns:

copy(deep: bool = False, name: str = None, **overwrite_params) → zfit.core.interfaces.ZfitObject
create_sampler(n: Union[int, tensorflow.python.framework.ops.Tensor, str] = None, limits: Union[Tuple[Tuple[float, ...]], Tuple[float, ...], bool] = None, fixed_params: Union[bool, List[zfit.core.interfaces.ZfitParameter], Tuple[zfit.core.interfaces.ZfitParameter]] = True) → zfit.core.data.Sampler

Create a Sampler that acts as Data but can be resampled, also with changed parameters and n.

If limits is not specified, space is used (if the space contains limits). If n is None and the model is an extended pdf, ‘extended’ is used by default.
Parameters:
  • n (int, tf.Tensor, str) –

    The number of samples to be generated. Can be a Tensor that will be or a valid string. Currently implemented:

    • ’extended’: samples poisson(yield) from each pdf that is extended.
  • () (fixed_params) – From which space to sample.
  • () – A list of Parameters that will be fixed during several resample calls. If True, all are fixed, if False, all are floating. If a Parameter is not fixed and its value gets updated (e.g. by a Parameter.set_value() call), this will be reflected in resample. If fixed, the Parameter will still have the same value as the Sampler has been created with when it resamples.
Returns:

py:class:~`zfit.core.data.Sampler`
Raises:
  • NotExtendedPDFError – if ‘extended’ is chosen (implicitly by default or explicitly) as an option for n but the pdf itself is not extended.
  • ValueError – if n is an invalid string option.
  • InvalidArgumentError – if n is not specified and pdf is not extended.
dtype

The dtype of the object

get_cache_deps(only_floating: bool = True) -> OrderedSet(['z', 'f', 'i', 't', '.', 'P', 'a', 'r', 'm', 'e'])

Return a set of all independent Parameter that this object depends on.

Parameters:only_floating (bool) – If True, only return floating Parameter
get_dependencies(only_floating: bool = True) -> OrderedSet(['z', 'f', 'i', 't', '.', 'P', 'a', 'r', 'm', 'e'])

DEPRECATED FUNCTION

Warning: THIS FUNCTION IS DEPRECATED. It will be removed in a future version. Instructions for updating: Use get_params instead if you want to retrieve the independent parameters or get_cache_deps in case you need the numerical cache dependents (advanced).

get_models(names=None) → List[zfit.core.interfaces.ZfitModel][source]
get_params(floating: Optional[bool] = True, is_yield: Optional[bool] = None, extract_independent: Optional[bool] = True, only_floating=<class 'zfit.util.checks.NotSpecified'>) → Set[zfit.core.interfaces.ZfitParameter]

Recursively collect parameters that this object depends on according to the filter criteria.

Which parameters should be included can be steered using the arguments as a filter.
  • None: do not filter on this. E.g. floating=None will return parameters that are floating as well as
    parameters that are fixed.
  • True: only return parameters that fulfil this criterion
  • False: only return parameters that do not fulfil this criterion. E.g. floating=False will return
    only parameters that are not floating.
Parameters:
  • floating – if a parameter is floating, e.g. if floating() returns True
  • is_yield – if a parameter is a yield of the _current_ model. This won’t be applied recursively, but may include yields if they do also represent a parameter parametrizing the shape. So if the yield of the current model depends on other yields (or also non-yields), this will be included. If, however, just submodels depend on a yield (as their yield) and it is not correlated to the output of our model, they won’t be included.
  • extract_independent – If the parameter is an independent parameter, i.e. if it is a ZfitIndependentParameter.
gradients(x: Union[float, tensorflow.python.framework.ops.Tensor], norm_range: Union[Tuple[Tuple[float, ...]], Tuple[float, ...], bool], params: Optional[Iterable[zfit.core.interfaces.ZfitParameter]] = None)
graph_caching_methods = [<function FunctionWrapperRegistry.__call__.<locals>.concrete_func>, <function FunctionWrapperRegistry.__call__.<locals>.concrete_func>, <function FunctionWrapperRegistry.__call__.<locals>.concrete_func>, <function FunctionWrapperRegistry.__call__.<locals>.concrete_func>, <function FunctionWrapperRegistry.__call__.<locals>.concrete_func>, <function FunctionWrapperRegistry.__call__.<locals>.concrete_func>]
instances = <_weakrefset.WeakSet object>
integrate(**kwargs)
models

Return the models of this Functor. Can be pdfs or funcs.

n_obs

Return the number of observables, the dimensionality. Corresponds to the last dimension.

name

The name of the object.

numeric_integrate(limits: Union[Tuple[Tuple[float, ...]], Tuple[float, ...], bool], norm_range: Union[Tuple[Tuple[float, ...]], Tuple[float, ...], bool] = None) → Union[float, tensorflow.python.framework.ops.Tensor]

Numerical integration over the model.

Parameters:
  • limits (tuple, ZfitSpace) – the limits to integrate over
  • norm_range (tuple, ZfitSpace, False) – the limits to normalize over
Returns:

the integral value
Return type:

Tensor
obs

Return the observables, string identifier for the coordinate system.

params
partial_analytic_integrate(**kwargs)
partial_integrate(**kwargs)
partial_numeric_integrate(**kwargs)
classmethod register_additional_repr(**kwargs)

Register an additional attribute to add to the repr.

Parameters:
  • keyword argument. The value has to be gettable from the instance (has to be an (any) –
  • or callable method of self. (attribute) –
classmethod register_analytic_integral(func: Callable, limits: Union[Tuple[Tuple[float, ...]], Tuple[float, ...], bool] = None, priority: Union[int, float] = 50, *, supports_norm_range: bool = False, supports_multiple_limits: bool = False) → None

Register an analytic integral with the class.

Parameters:
  • func (callable) –

    A function that calculates the (partial) integral over the axes limits. The signature has to be the following:

    • x (ZfitData, None): the data for the remaining axes in a partial
      integral. If it is not a partial integral, this will be None.
    • limits (ZfitSpace): the limits to integrate over.
    • norm_range (ZfitSpace, None): Normalization range of the integral.
      If not supports_supports_norm_range, this will be None.
    • params (Dict[param_name, zfit.Parameters]): The parameters of the model.
    • model (ZfitModel):The model that is being integrated.
  • () (limits) – |limits_arg_descr|
  • priority (int) – Priority of the function. If multiple functions cover the same space, the one with the highest priority will be used.
  • supports_multiple_limits (bool) – If True, the limits given to the integration function can have multiple limits. If False, only simple limits will pass through and multiple limits will be auto-handled.
  • supports_norm_range (bool) – If True, norm_range argument to the function may not be None. If False, norm_range will always be None and care is taken of the normalization automatically.
register_cacher(cacher: Union[zfit.core.interfaces.ZfitCachable, Iterable[zfit.core.interfaces.ZfitCachable]])

Register a cacher that caches values produces by this instance; a dependent.

Parameters:() (cacher) –
classmethod register_inverse_analytic_integral(func: Callable) → None

Register an inverse analytical integral, the inverse (unnormalized) cdf.

Parameters:() (func) –
reset_cache(reseter: zfit.util.cache.ZfitGraphCachable)
reset_cache_self()

Clear the cache of self and all dependent cachers.

sample(n: Union[int, tensorflow.python.framework.ops.Tensor, str] = None, limits: Union[Tuple[Tuple[float, ...]], Tuple[float, ...], bool] = None) → zfit.core.data.SampleData

Sample n points within limits from the model.

If limits is not specified, space is used (if the space contains limits). If n is None and the model is an extended pdf, ‘extended’ is used by default.

Parameters:
  • n (int, tf.Tensor, str) –

    The number of samples to be generated. Can be a Tensor that will be or a valid string. Currently implemented:

    • ’extended’: samples poisson(yield) from each pdf that is extended.
  • limits (tuple, ZfitSpace) – In which region to sample in
Returns:

SampleData(n_obs, n_samples)
Raises:
  • NotExtendedPDFError – if ‘extended’ is (implicitly by default or explicitly) chosen as an option for n but the pdf itself is not extended.
  • ValueError – if n is an invalid string option.
  • InvalidArgumentError – if n is not specified and pdf is not extended.
space
update_integration_options(draws_per_dim=None, mc_sampler=None)

Set the integration options.

Parameters:
  • draws_per_dim (int) – The draws for MC integration to do
  • () (mc_sampler) –
zfit.models.basefunctor.extract_daughter_input_obs(obs: Union[str, Iterable[str], zfit.Space], spaces: Iterable[zfit.core.interfaces.ZfitSpace]) → zfit.core.interfaces.ZfitSpace[source]

Extract the common space from spaces by combining them, test against obs.

The obs are assumed to be the obs given to a functor while the spaces are the spaces of the daughters. First, the combined space from the daughters is extracted. If no obs are given, this is returned. If obs are given, it is checked whether they agree. If they agree, and no limit is set on obs (i.e. they are pure strings), the inferred limits are used, sorted by obs. Otherwise, obs is directly used.

Parameters:
  • obs
  • spaces

Returns: