A set of tools for estimating LHCb PID efficiencies
Project description
PIDCalib2
A set of software tools for estimating LHCb PID efficiencies.
The package includes several user-callable modules:
make_eff_hists
creates histograms that can be used to estimate the PID efficiency of a user's sampleref_calib
calculates the LHCb PID efficiency of a user reference samplemerge_trees
merges two ROOT files with compatibleTTree
splot_calib_distributions
allows you to plot distributions of variables in the calibration datasetspklhisto2root
converts Pickled boost-histograms to ROOT histograms
The term "reference dataset/sample" refers to the user's dataset to which they want to assign PID efficiencies. The "calibration datasets/samples" are the special, centrally managed samples used internally by PIDCalib for PID efficiency estimation. The --sample
argument always concerns these calibration samples.
Slides with additional information, example output, and plots are available on Indico.
Setup
When working on a computer where the LHCb software stack is available (LXPLUS, university cluster, etc.), one can setup PIDCalib2 by running
lb-conda pidcalib bash
After this, the following commands will be available
pidcalib2.make_eff_hists
pidcalib2.ref_calib
pidcalib2.merge_trees
pidcalib2.plot_calib_distributions
pidcalib2.pklhisto2root
You can skip the bash invocation and join the setup and run phases into a single command
lb-conda pidcalib pidcalib2.make_eff_hists
To run make_eff_hists
, you will need access to CERN EOS. You don't need to do anything special on LXPLUS. On other machines, you will usually need to obtain a Kerberos ticket by running
kinit [username]@CERN.CH
Installing from PyPI
The PIDCalib2 package is available on PyPI. It can be installed on any computer via pip
simply by running (preferably in a virtual environment; see venv
)
pip install pidcalib2
Note that this will install the xrootd
Python bindings. One also has to install XRootD itself for the bindings to work. See this page for XRootD releases and instructions.
make_eff_hists
This module creates histograms that can be used to estimate the PID efficiency of a user's sample.
Reading all the relevant calibration files can take a long time. When running a configuration for the first time, we recommend using the --max-files 1
option. This will limit PIDCalib2 to reading just a single calibration file. Such a test will reveal any problems with, e.g., missing variables quickly. Keep in mind that you might get a warning about empty bins in the total histogram as you are reading a small subset of the calibration data. For the purposes of a quick test, this warning can be safely ignored.
Options
To get a usage message listing all the options, their descriptions, and default values, type
pidcalib2.make_eff_hists --help
The calibration files to be processed are determined by the sample
, magnet
, and particle
options. All the valid combinations can be listed by running
pidcalib2.make_eff_hists --list configs
Aliases for standard variables are defined to simplify the commands. We recommend users use the aliases when specifying variables. When you use a name that isn't an alias, a warning message like the following will show up in the log.
'probe_PIDK' is not a known PID variable alias, using raw variable
All aliases can be listed by running
pidcalib2.make_eff_hists --list aliases
Note that there are many more variables than there are aliases. If you want to find a variable for which no alias exists, you can check one of the calibration files yourself. The paths to the calibration files are printed when the --verbose
option is specified. Alternatively, you can simply guess the name - if it doesn't exist, PIDCalib2 will let you know and might provide a list of similar names that do exist.
A file with alternative binnings can be specified using --binning-file
. The file must contain valid JSON specifying bin edges. For example, two-bin binnings for particle Pi
, variables P
and PT
can be defined as
{"Pi": {"P": [10000, 15000, 30000], "PT": [6000, 10000, 20000]}}
An arbitrary number of binnings can be defined in a single file.
Complex cut expressions can be created by chaining simpler expressions using &
(logical and) and |
(logical or). One can also use standard mathematical symbols, like *
, /
, +
, -
, (
, )
. Whitespace does not matter.
Examples
-
Create a single 3D efficiency histogram for a single PID cut
pidcalib2.make_eff_hists --sample Turbo18 --magnet up --particle Pi --pid-cut "DLLK > 4" --bin-var P --bin-var ETA --bin-var nSPDhits --output-dir pidcalib_output
-
Create multiple histograms in one run (most of the time is spent reading in data, so specifying multiple cuts is much faster than running make_eff_hists sequentially)
pidcalib2.make_eff_hists --sample Turbo16 --magnet up --particle Pi --pid-cut "DLLK > 0" --pid-cut "DLLK > 4" --pid-cut "DLLK > 6" --bin-var P --bin-var ETA --bin-var nSPDhits --output-dir pidcalib_output
-
Create a single efficiency histogram for complex cuts using only negatively charged tracks
pidcalib2.make_eff_hists --sample Turbo18 --magnet up --particle Pi --pid-cut "MC15TuneV1_ProbNNp*(1-MC15TuneV1_ProbNNpi)*(1-MC15TuneV1_ProbNNk) < 0.5 & DLLK < 3" --cut "IsMuon==0 & Brunel_PT>250 & trackcharge==-1" --bin-var P --bin-var ETA --bin-var nSPDhits --output-dir pidcalib_output
Caveats
Not all datasets have all the variables, and in some cases, the same variable is named differently (e.g., probe_Brunel_IPCHI2
is named probe_Brunel_MINIPCHI2
in certain electron samples). The aliases correspond to the most common names, but you might need to check the calibration files if PIDCalib2 can't find the variable you need.
ref_calib
This module uses the histograms created by make_eff_hists
to assign efficiency to events in a reference sample supplied by the user. Adding efficiency to the user-supplied file requires PyROOT and is optional.
The module works in two steps:
- Calculate the efficiency and save it as a TTree in a separate file.
- Optionally copy the efficiency TTree to the reference file and make it a friend of the user's TTree. The user must request the step by specifying
--merge
on the command line.
Be aware that --merge
will modify your file. Use with caution.
Options
The sample
and magnet
options are used solely to select the correct PID efficiency histograms. They should therefore mirror the options used when running make_eff_hists
.
bin-vars
must be a dictionary that relates the binning variables (or aliases) used to make the efficiency histograms with the variables in the reference sample. We assume that the reference sample branch names have the format [ParticleName]_[VariableName]
. E.g., D0_K_calcETA
, corresponds to a particle named D0_K
and variable calcETA
. If the user wants to estimate PID efficiency of their sample using 1D binning, where calcETA
corresponds to the ETA
binning variable alias of the calibration sample, they should specify --bin-vars '{"ETA": "calcETA"}'
.
ref-file
is the user's reference file to which they want to assign PID efficiencies. The parameter can be a local file or a remote file, e.g., on EOS (--ref-file root://eoslhcb.cern.ch//eos/lhcb/user/a/anonymous/tuple.root
).
ref-pars
must be a dictionary of particles from the reference sample to apply cuts to. The keys represent the particle branch name prefix (D0_K
in the previous example), and the values passed are a list containing particle type and PID cut, e.g. '{"D0_K" : ["K", "DLLK > 4"], "D0_Pi" : ["Pi", "DLLK < 4"]}'
.
The --merge
option will copy the PID efficiency tree to your input file and make the PID efficiency tree a "Friend" of your input tree. Then you can treat your input tree as if it had the PID efficiency branches itself. E.g., input_tree->Draw("PIDCalibEff")
should work. ROOT's "Friend" mechanism is an efficient way to add branches from one tree to another. Take a look here if you would like to know more.
Examples
- Evaluate efficiency of a single PID cut and save it to
user_ntuple_PID_eff.root
without adding it touser_ntuple.root
pidcalib2.ref_calib --sample Turbo18 --magnet up --ref-file data/user_ntuple.root --histo-dir pidcalib_output --bin-vars '{"P": "mom", "ETA": "Eta", "nSPDHits": "nSPDhits"}' --ref-pars '{"Bach": ["K", "DLLK > 4"]}' --output-file user_ntuple_PID_eff.root
- Evaluate efficiency of a single PID cut and add it to the reference file
user_ntuple.root
pidcalib2.ref_calib --sample Turbo18 --magnet up --ref-file data/user_ntuple.root --histo-dir pidcalib_output --bin-vars '{"P": "mom", "ETA": "Eta", "nSPDHits": "nSPDhits"}' --ref-pars '{"Bach": ["K", "DLLK > 4"]}' --output-file user_ntuple_PID_eff.root --merge
- Evaluate efficiency of multiple PID cuts and add them to the reference file
pidcalib2.ref_calib --sample Turbo18 --magnet up --ref-file data/user_ntuple.root --histo-dir pidcalib_output --bin-vars '{"P": "P", "ETA": "ETA", "nSPDHits": "nSPDHits"}' --ref-pars '{"Bach": ["K", "DLLK > 4"], "SPi": ["Pi", "DLLK < 0"]}' --output-file user_ntuple_PID_eff.root --merge
Caveats
You might notice that some of the events in your reference sample are assigned PIDCalibEff
, PIDCalibErr
, or both of -999.
PIDCalibEff
is -999 when for at least one track- The event is out of binning range
- The relevant bin in the efficiency histogram has no events whatsoever
- The efficiency is negative
PIDCalibErr
is -999 when for at least one track- The event is out of binning range
- The relevant bin in the efficiency histogram has no events whatsoever
- The relevant bin in the efficiency histogram has no events passing PID cuts
- The efficiency is negative
Because of double
→ float
conversion in the original PIDCalib, tiny discrepancies (<1e−3 relative difference) in the efficiencies and/or uncertainties are to be expected.
A bug in the original PIDCalib caused the electron calibration datasets to be read twice, resulting in incorrect efficiency map uncertainties.
The original PIDCalib didn't apply the correct cuts to Omega samples (K_Omega
and K_DD
), leading to non-sensical efficiency maps.
plot_calib_distributions
This tool allows you to plot distributions of variables in the calibration datasets. You can supply the same cuts and custom binnings that you would use for make_eff_hists
. If you wish to plot a variable for which no binning exists, a uniform binning with 50 bins will be used. You can change the number of bins using --bins
and force a uniform binning even if another binning is defined via --force-uniform
.
A plot for every requested variable will be created in the --output-dir
directory. The format of the plots can be controlled by --format
. Furthermore, plot_calib_distributions.pkl
will be saved in the same directory, containing all the histograms, should the user want to make the plots manually.
Examples
- Create plots of the variables DLLK and P using 1 calibration file
pidcalib2.plot_calib_distributions --sample Turbo18 --magnet up --particle Pi --bin-var DLLK --bin-var P --output-dir pidcalib_output --max-files 1
- Create PDF plots of variable P with 95 uniform bins
pidcalib2.plot_calib_distributions --sample Turbo18 --magnet up --particle Pi --bin-var P --output-dir pidcalib_output --max-files 1 --format pdf --force-uniform --bins 95
- Create plots of variable P using custom binning
pidcalib2.plot_calib_distributions --sample Turbo18 --magnet up --particle Pi --bin-var P --output-dir pidcalib_output --max-files 1 --format png --binning-file my_binning.json
pklhisto2root
This tool converts pickled PIDCalib2 histograms to TH*D
and saves them in a ROOT file. It can be used on histograms produced by make_eff_hists
or plot_calib_distributions
. Note that ROOT supports only 1-, 2-, and 3-dimensional histograms; attempting to convert higher-dimensional histograms will fail.
Example
- Convert pickled boost_histograms from
make_eff_hists
to ROOTpidcalib2.pklhisto2root "pidcalib_output/effhists-Turbo18-up-Pi-DLLK>4-P.ETA.nSPDhits.pkl"
This will translate the histograms and save them topidcalib_output/effhists-Turbo18-up-Pi-DLLK>4-P.ETA.nSPDhits.root
.
Development
With lb-conda
On machines where lb-conda
is available, you may use the pidcalib
environment for PIDCalib2 development. This is mainly useful for small modifications and only if you don't need to add any new dependencies.
- Clone the repository from GitLab
- Enter the PIDCalib2 directory
cd pidcalib2
- Start a new BASH shell within the
pidcalib
environment
lb-conda pidcalib bash
- Run your local PIDCalib2 code
cd src
python -m pidcalib2.make_eff_hists -h
Without lb-conda
This is a more versatile (if convoluted) method. It gives you full control of the dev environment and the ability to use IDEs, etc.
- Clone the repository from GitLab
- Enter the PIDCalib2 directory
cd pidcalib2
- (Optional) Set up a virtual environment
python3 -m venv .venv source .venv/bin/activate
- Install pinned dependencies
pip install -r requirements-dev.txt
- Install
xrootd
(possibly manually; see this issue) - Run the tests
pytest
- Run the modules
cd src python3 -m pidcalib2.make_eff_hists -h
Tips
Certain tests can be excluded using markers like this
pytest -m "not xrootd"
See available markers by running pytest --markers
(the list will start with PIDCalib2 custom markers, then it will include all the pytest built-in markers).
Links
- PIDGen2 - a tool to resample MC PID variables based on distributions from data calibration samples
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