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1 pam-fi 1.1 \documentclass{article}
2    
3     \title{PamCut Developer's Guide}
4     \author{Nicola Mori}
5    
6     \begin{document}
7     \maketitle
8     \tableofcontents
9     \section{The philosophy}
10    
11     {\bf PamCut} is an abstract class, defining the interface for a cut object used
12     in the analysis of PAMELA data. The main idea beyond the development is that a
13     cut object must be capable of saying if an event is good or not, ie., if it
14     satisfies some selection criteria. This criteria have to be implemented from
15     scratch every time a specific cut is needed, by defining a concrete class which
16     inherits form {\bf PamCut} and provides an implementation for the pure virtual
17     method {\bf Check}.
18     A special derived class is {\bf PamCutCollection}. This is a sort of a
19     container for basic cuts, and is considered as a single cut. Its {\bf Check}
20     implementation simply invokes all the {\bf Check}s of the single cuts, and it
21     is successful if all the single cuts are succesful.
22     {\bf PamCut} also provides the interface for two methods for post-processing:
23     {\bf OnGood} and {\bf OnBad}. In derived classes these can contain specific
24     tasks to be performed whenever an event satisfy the {\bf Check} condition or
25     not. The method {\bf ApplyCut} takes care of invoking {\bf Check} and
26     subsequently calls {\bf OnGood} or {\bf OnBad} according to the result of {\bf Check}.
27     Summarizing, {\bf Check}ing an event simply means to ask the object if the
28     event satisfy the selection criteria; applying a cut means to check and then
29     perform post-selection tasks. The cut can be applied to a bunch of events by
30     means of the {\bf Process} method.
31    
32     \subsection{More on collections}
33     A collection is an object which inherits from {\bf PamCutCollection}, which in
34     turn inherits from {\bf PamCut}. So a collection is a cut itself, meaning that
35     its interface contains a {\bf Check} method, an {\bf ApplyCut} method and so
36     on. Logically, this is in agreement with the fact that a bunch of cuts can be
37     thought of as a single cut whose result is the logical AND of all the basic
38     cuts. More specifically, the implementation chosen for {\bf PamCutCollection}
39     methods consists in simply performing a cyclic call of the corresponding
40     methods in basic cuts. So {\bf PamCutCollection::Check} will subsequently call
41     all the {\bf Check} methods of the basic cuts it contains, and {\bf
42     PamCutCollection::ApplyCut} will call the basic {\bf ApplyCut}s. This last
43     feature deserves some more words. When the collection calls a basic {\bf
44     ApplyCut}, the basic cut will also perform its specific post-selection tasks as
45     defined in its implementations of {\bf OnGood} and {\bf OnBad}. If all the
46     basic cuts result to be satisfied, then {\bf PamCutCollection::ApplyCut} will
47     call {\bf PamCutCollection::OnGood}, allowing for the execution of a
48     post-processing task which occurs only if all the basic selection criteria are
49     satisfied. Indeed, as said above a collection is a cut, so it behaves exactly
50     like a cut: when you apply it, you will also do the apprpriate post-processing.
51     We have then two levels of post-processing: the first is triggered by success
52     of a basic cut, the second by the success of the whole sequence of basic cuts.
53     This modular behaviour achieved with collections allow for a definition of a
54     hierarchy of cuts: a collection can contain other collections, which in turn
55     can contain other collections or basic cuts, in a tree-like hierarchy. Each
56     level has its own post-selection tasks, allowing for a fine control of the
57     post-processing procedure.
58    
59     To perform some tests it could be useful to have a collection which applies
60     the whole bunch cuts to all the events, regardless if some cuts are not
61     satisfied for a specific event ({\bf PamCutCollection} stop the evaluation for
62     the current event as soon as a cut is not satisfied). This is achieved with the
63     {\bf BlindCutCollection} class, which blindly checks all the cuts for all the
64     events. This will lead to a call to {\bf OnGood} or {\bf OnBad} for all the
65     cuts for each event; the collection will the call its own {\bf OnGood} or {\bf
66     OnBad} if all the cuts have been satisfied or not, much like in
67     {\bf PamCutCollection}. See the Doxygen html documentation for more info about
68     {\bf BlindCutCollection} and other specific cut implementations.
69    
70     \section{Actions and the SmartCollection}
71     When performing an analysis, each time an event is selected as good some
72     actions are likely to be performed, like filling histograms or writing a
73     report. To automate these tasks, the class {\bf CollectionAction} has been
74     designed. A {\bf CollectionAction} object has a {\bf Setup} method which
75     may contain the initialization procedures, like reading parameters from a file.
76     Also the constructor can contain some initializations. The finalization, like
77     writing histograms on a file, is in the {\bf Finalize} method. The specific
78     actions for good and bad events are to be defined in the {\bf OnGood} and {\bf
79     OnBad} methods, much like in collections. {\bf CollecionAction} is an abstract
80     class, which does nothing but defining the interface. Its concrete
81     implementations will be called actions.\\
82     Actions are automatically handled by the {\bf SmartCollection} class. It
83     inherits from {PamCutCollection}, and contains a vector of {\bf
84     CollectionAction} objects. These actions can be added using {\bf
85     SmartCollection::AddAction}; for each of them, the collection will take care of
86     calling {\bf Setup} at the beginning of the analysis, {\bf OnGood} and {\bf
87     OnBad} for every event (depending on the selection result), and {\bf Finalize}
88     at the end of the analysis. In all other aspects, it behaves exactly as {\bf
89     PamCutCollection}.\\
90     Loosely speaking, after defining an action one simply has to instantiate it,
91     add it to a {\bf SmartCollection} and launch the analysis (fire and
92     forget\ldots).
93    
94     \section{The software organization}
95     The software is organized in a tree of directories. The idea is that each node
96     of this tree must provide the necessary informations about the sub-branches. In
97     each directory, a header file will contain \verb1#include1 directives for all
98     header files in the sub-directories. This way, it is sufficient to include the
99     top-level header in the analysis software to automatically include all the
100     headers of the project. This top-level header is {\it PamCutEnv.h}. Each time a
101     sub-directory is created, the headers it contains must be included in the
102     parent node's header.
103    
104     \subsection{The makefile organization}
105     The instructions to build the software library are encoded in the standard {\bf
106     make} way, following the same tree structure of the software. Each node
107     directory contains an {\it include.mk} file, which includes all the
108     {include.mk} in the sub-directories. This chain of inclusions terminates on the
109     leaves, which most of the times contain the definition and implementation of
110     the classes. Each leaf directory must provide build instructions for the files
111     it contains, in a file called {\it subdir.mk}; this file has to be included in
112     the upper {\it include.mk}. The top level {\it include.mk} is included by
113     the {\it makefile}.\\
114     This way, each directory takes care of its sub-directories, letting a quick and
115     easy addition of the latters.
116    
117     \section{The software architecture}
118     The software is organized in a tree of directories. The root folder contains a
119     {\it PamCutBase} folder, in which the definitions of the base classes ({\bf
120     PamCut} and {\bf PamCutCollection}) are stored, and the general headers {\it
121     PamCutEnv.h} and {\it CommonDefs.h}. {\it PamCutEnv.h} contains the inclusion
122     of all the headers of the framework, allowing for the use of the entire
123     software with only one \verb1#include1 in the code; {\it CommonDefs.h} contains
124     all the definitions which are relevant for the entire framework.
125     To develop a specific cut one has to define a derived class from {\bf PamCut},
126     which at least must provide a concrete implementation of {\bf Check}. One can
127     also define new versions of {\bf OnGood} and {\bf OnBad} for specific
128     post-selection tasks (in the base class these methods do nothing). Be very
129     careful if you decide to redefine {\bf ApplyCut}: remeber that the interface
130     requires them to call the post-selection routines.
131     A good rule for keeping the software distribution clean is to use a different
132     folder for each cut definition, named as the cut itself. When you define a new
133     cut, create a folder named as the cut inside an adequate parent directory and
134     place the {\it .h} and {\it .cpp} files inside it. To speed up development, you may copy
135     and paste an existing cut and then modify it.\\
136     In the same way, actions can be defined.
137    
138     \section{How to define a cut}
139     As said above, to define a cut (let's name it {\bf DummyCut}) it is suggested
140     to create a folder {\it DummyCut} inside, eg., a {\bf DummyDir} directory
141     inside the root folder, and to create inside it two files: {\it DummyCut.h},
142     which will contain all the declarations, and {\it DummyCut.cpp}, where the
143     implementation will be coded. A typical structure for {\it DummyCut.h} would be:
144    
145     \begin{verbatim}
146     #ifndef DUMMYCUT_H_
147     #define DUMMYCUT_H_
148    
149     /*! @file DummyCut.h The DummyCut class declaration file */
150    
151     #include "../../PamCutBase/PamCutBase.h"
152    
153     /*! @brief An example cut. */
154     class DummyCut: public PamCut {
155     public:
156    
157     /*! @brief Constructor. */
158     Dummy(char *cutName):
159     PamCut(cutName) {
160     }
161    
162     /*! @brief Destructor. */
163     ~DummyCut() {
164     }
165    
166     /*! @brief The dummy cut check
167     *
168     * This routine checks the event using the dummy cut criteria.
169     *
170     * @param event The event to analyze.
171     * @return CUTOK if the dummy cut is satisfied
172     */
173     int Check(PamLevel2 *event);
174    
175     };
176    
177     #endif /* DUMMYCUT_H_ */
178    
179     \end{verbatim}
180    
181     Note the inclusion of {\it PamCutBase.h}: this is essential to let {\bf
182     DummyClass} know about its parent class, which in this case is {\bf PamCut}.
183     Another thing to care about is the multiple inclusion protection, ie., the
184     preprocessor directives:
185     \begin{verbatim}
186     #ifndef DUMMYCUT_H_
187     #define DUMMYCUT_H_
188     .
189     .
190     .
191     #endif /* DUMMYCUT_H_ */
192     \end{verbatim}
193     This provide protection against multiple inclusion of a header in a single
194     compilation unit due to circular inclusion; in practice, it will save the
195     developer a lot of double definition errors from the compiler. Be sure that all
196     your headers are encapsulated in such a structure, and that for each header
197     there is a different name after \verb1#ifndef1 (which must match the successive
198     \verb1#define1); otherwise, the compiler could skip the inclusion of some
199     headers. The convention adopted in {\bf PamCut} for such tags is:
200     \verb1<Filename in uppercase>_H_1, which provides univocal tags for each header.
201    
202     The essential redeclarations are: the constructor, the desctructor and {\bf
203     Check}. Constructor deserves some observations: since constructors are not
204     inherited, each class must have its own. However, if a class has a parent
205     class, it is necessary to initialize also the parent class. If the parent class
206     has a default constructor (ie., a constructor without arguments) the compiler
207     will automatically call it and the user has nothing to worry about. However,
208     {\bf PamCut} has no default constructor, so in every derived class there must
209     be an explicit call to the {\bf PamCut} constructor. This is what is done in
210     the lines:
211    
212     \begin{verbatim}
213     Dummy(char *cutName):
214     PamCut(cutName) {
215     }
216     \end{verbatim}
217     {\bf PamCut} objects have a name, internally stored in the {\bf \_cutName}; so
218     our {\bf DummyClass}, since it inherits from {\bf PamCut}, must also have a
219     name. Its constructor, indeed, requires a string containing the cut's name. But
220     in {\bf DummyCut} there's no local variable to store it, and there's no need to
221     define one since it is already present in {\bf PamCut}. The only thing to do is
222     to initialize it exactly as {\bf PamCut} would do: this is the purpose of
223     invoking \verb1PamCut(cutName)1. As an aside, what follows the colon after the
224     {\bf DummyCut} constructor declaration is called \emph{initialization list}:
225     here one can (and must) call the constructors for all the objects and variables
226     contained in the class. These are executed before the class constructor's body,
227     so that one can safely assume that at construction time all the internal
228     objects and variables are properly initialized.
229    
230     To recap and generalize, when you write a derived class you must always call
231     the constructor of its parent class, which will take care about initializing
232     the ``parent core'' of the derived class.
233    
234     One can also redefine {\bf OnGood}, {\bf OnBad}, add new methods, variables and
235     so on. If you plan to build a general purpose cut who could be used by
236     different people please take the time to add the appropriate documentation to
237     the code. In the example, Doxygen comment lines (beginning with \verb1/*!1)
238     are shown; an on-line guide for Doxygen can be found at:
239     \newline
240     \newline
241     \verb1 http://www.stack.nl/~dimitri/doxygen/manual.html1
242    
243     \vspace{.5cm}
244     Once the header has been prepared, it's time to implement the cut into {\it
245     DummyCut.cpp}:
246    
247     \begin{verbatim}
248     /*! @file DummyCut.cpp The DummyCut class implementation file */
249    
250     #include "DummyCut.h"
251    
252     int DummyCut::Check(PamLevel2 * event) {
253    
254     if (<Some condition about the event>)
255     return CUTOK;
256     else
257     return 0;
258     }
259     \end{verbatim}
260    
261     In this very simple implementation a basic feature is noticeable: the interface
262     requires that whenever an event satisfy the selection criterion, {\bf Check}
263     must return the {\bf CUTOK} value. This value is defined in {\it CommonDefs.h}.
264     The return value for a discarded event is implementation-specific, and can be
265     anything but {\bf CUTOK}. This return value could take different values
266     depending on the reason why the event has been discarded: for example, it can
267     be a number associated to a specific detector whose data is missing in a data
268     quality cut. It is then passed to {\bf OnBad}, which can perform some task
269     depending on the specific reason of the cut failure (eg., on which detector has
270     no data).
271     Remember also to include the header file.
272    
273     \section{How to setup the cut's build} \label{sec:build}
274     Once a cut has been declared and implemented, the makefiles have to be adjusted
275     to include it in the cut library. The {\it makefile} provided with the software
276     will build a library called {\it libPamCut.so}, which can be then linked to a
277     specific analysis code. It is based on a submakefile structure. Each folder
278     containing a cut must also include one of these submakefiles (named {\it
279     subdir.mk} by convention), who instructs the main {\it makefile} on how to build
280     the newly added cut. An example is:
281    
282     \begin{verbatim}
283     # Choose a name for the object file. This must coincide with the
284     # .cpp and .h filename, except for the extension which has to
285     # be .o
286     OBJS += ./DummyDir/DummyCut/DummyCut.o
287    
288     # Dependencies file. The extension must be .d, and the name equal
289     # to the cut name.
290     CPP_DEPS += ./DummyDir/DummyCut/DummyCut.d
291    
292     # Rules for compilation. You will likely have only to specify
293     # the path. Put the directory path:
294     # here here
295     ./DummyDir/DummyCut/%.o: ./DummyDir/DummyCut/%.cpp
296     @echo 'Building file: $<'
297     @echo 'Invoking: GCC C++ Compiler'
298     $(C++) -I${ROOTSYS}/include -I${PAM_INC} -I${PAM_INC}/yoda \
299     -Wall -c -MMD -MP -MF"$(@:%.o=%.d)" -MT"$(@:%.o=%.d)"\
300     -o"$@" "$<"
301     @echo 'Finished building: $<'
302     @echo ' '
303    
304     \end{verbatim}
305    
306     Existing files can be used as a template. The first thing you have to modify
307     is the object name (\verb1OBJS1 variable): be careful to append the object name
308     to \verb1OBJS1 using \verb1+=1 instead of overwriting it with \verb1=1. The
309     paths in this file will be relative to the root directory where the {\it
310     makefile} is, eg., \verb1./1 is not the {\it DummyCut} directory where {\it
311     subdir.mk} is, but the root directory which contains the {\it makefile}. The
312     object file ({\it DummyCut.o}) must be named as the cut and the directory that
313     contains the cut. The \verb1CPP_DEPS1 variable must be similarly modified.
314     This variable contains a list of dependency files, which contains all the
315     external headers (eg., PAMELA and ROOT headers) {\bf PamCut} depends on. These
316     lists are automatically generated, and allows {\it make} to rebuild {\bf
317     PamCut} whenever one of these headers are modified. Finally, one has also to
318     put the directory name in the target line which precedes the build command,
319     just below \verb1here1.
320    
321     After creating the {\it subdir.mk}, it must be included in the {\it include.mk}
322     in the parent directory. It looks like this:
323    
324     \begin{verbatim}
325     # Include here the submakefiles for each cut
326    
327     # Cuts
328     -include DummyDir/DummyCut/subdir.mk
329     .
330     .
331     .
332     \end{verbatim}
333    
334    
335     Remember to write paths as relative to the root directory. Going backward along
336     the chain of inclusions leads to the {\it makefile}:
337    
338     \begin{verbatim}
339     # ------------------------ Build options ----------------------#
340    
341     # C++ compiler and linker
342     C++ = g++
343    
344     # Optimization flags.
345     OPTIMIZE = -g3 #-DDEBUGPAMCUT
346    
347     # Library flags
348     EXCLUSIONFLAGS = #-DNO_TOFNUCLEI -DNO_CALONUCLEI -DNO_TRKNUCLEI
349    
350     COMMONDEPS = makefile
351    
352     -include include.mk
353    
354     #------------------------ Make body ---------------------------#
355     #
356     # Below the make commands are defined. There are no options to
357     # set in this section, so it has to be modified only in case of
358     # radical changes to the make procedure.
359    
360     # Remove command for clean
361     RM := rm -rf
362    
363     # Additional dependencies from headers of other software
364     # (PAMELA, ROOT)
365     ifneq ($(MAKECMDGOALS),clean)
366     ifneq ($(strip $(CPP_DEPS)),)
367     -include $(CPP_DEPS)
368     endif
369     endif
370    
371     # All Target
372     all: version libPamCut.so
373    
374     # Tool invocations
375     libPamCut.so: $(OBJS) $(USER_OBJS)
376     @echo 'Building target: $@'
377     @echo 'Invoking: GCC C++ Linker'
378     $(C++) -shared -o"libPamCut.so" $(OBJS)
379     @echo 'Finished building target: $@'
380     @echo ' '
381    
382     # Other Targets
383     clean:
384     -$(RM) $(CPP_DEPS) $(OBJS) libPamCut.so
385     -@echo ' '
386    
387     version:
388     @gcc --version | grep gcc; echo
389    
390     .PHONY: all clean dependents version
391     \end{verbatim}
392    
393     The Build options section is the one that will most likely need a modification
394     if one wants to tweak the compilation; the make body will most of the times be
395     good as it is. The {\it makefile} contains comments to explain how to set the
396     various options.\\
397     The first option to set is the compiler: g++ will work on
398     almost all Linux systems. Next is the optimization level, which could be set to
399     one of the proposed values according to the specific necessities. The {\it
400     makefile} comments contains also instructions on how to enable debug sections
401     in the code.\\
402     Since the PAMELA software is modular, in some setups it may lack some libraries
403     needed by some cuts. When designing such a cut it is a good habit to setup
404     its eventual exclusion from the library. This can be efficiently done using
405     the compiler directive \verb1#ifdef1. For example, encapsulating all the code
406     in the header and implementation files of {\bf DummyCut} in a structure like
407     this:
408    
409     \begin{verbatim}
410     #ifdef NO_DUMMYCUT
411     .
412     .
413     .
414     #endif
415     \end{verbatim}
416    
417     \noindent will completely exclude {\bf DummyCut} from the environment if the
418     flag \verb1NO_DUMMYCUT1 is defined. It can be done passing the parameter
419     \verb1-DNO_DUMMYCUT1 to the compiler. These exclusion flags can be defined in
420     the \verb1EXCLUSIONFLAGS1 variable. A concrete example is given by
421     {\bf TofNucleiZCut}, which requires the {\bf ToFNuclei} library: look at it to
422     see how its exclusion from the code is implemented, allowing to build and use
423     {\bf PamCut} in those environments that do not include {\bf ToFNuclei}. In the
424     end, this is very similar to what is done with the debug sections.\\
425     The \verb1COMMONDEPS1 flag contains the files which, if modified, will trigger
426     a complete rebuild of the library. For example, if you change the {\it
427     makefile} by modifying an optimization option all the modules should be rebuilt
428     so that the whole library will have the same level of optimization. That's why
429     {\it makefile} is in \verb1COMMONDEPS1. Add all the other files that should
430     behave like this.\\
431    
432     If you need some extra modifications to the building system you need to know
433     more about {\it make}; an online guide is at:
434     \newline
435     \verb1http://www.linuxtopia.org/online_books/programming_tool_guides/1
436     \newline
437     \verb1 gnu_make_user_guide/make.html#SEC_Top1
438    
439    
440     \section{How to define an action}
441     Defining an action is very similar to defining a cut. An example header:
442    
443     \begin{verbatim}
444     #ifndef DUMMYACTION_H_
445     #define DUMMYACTION_H_
446    
447     #include "../CollectionAction/CollectionAction.h"
448    
449     /*! @brief A dummy action definition. */
450     class DummyAction: public CollectionAction {
451    
452     public:
453     /*! @brief Constructor.
454     *
455     * @param actionName The action's name.
456     */
457     DummyAction(const char *actionName):
458     CollectionAction(actionName){}
459    
460     /*! @brief Destructor */
461     ~DummyAction() {
462     }
463    
464     /*! @brief The setup procedure.
465     *
466     * @param events The events pointer.
467     */
468     void Setup(PamLevel2 *events);
469    
470     /*! @brief The OnGood procedure.
471     *
472     * @param event The selected event.
473     */
474     void OnGood(PamLevel2 *event);
475    
476     /*! @brief Writes the tree of saved events to the output file. */
477     void Finalize();
478     };
479    
480     #endif /* DUMMYACTION_H_ */
481    
482     \end{verbatim}
483    
484     The {\bf DummyAction} declaration above is a good example. The action classes
485     must inherit from {\bf CollectionAction}, and their constructor have to call
486     the constructor of the ancestor class in the initialization list, similarly to
487     what happens for cuts. Then some of the base class' methods are overridden,
488     specifically {\bf Setup}, {\bf OnGood} and {\bf Finalize}. The last two methods
489     have to be overridden, since they are pure virtual (an action is supposed to do
490     something for good events and something to end the analysis, so making these
491     methods pure virtual is a way to enforce a definition in the derived classes).
492     Conversely, {\bf Setup} and {\bf OnBad} are concrete in the base class, with
493     void implementation: since not all actions would need a setup (it can be done
494     also in the constructor) or a procedure for bad events, this implementation
495     allows to not define them in derived classes. Obviously, the re-declared
496     methods in the header have to have a re-definition in a .cpp file, exactly as
497     for the cuts.
498    
499     \section{How to setup the actions's build}
500     This topic is very similar to that explained in sec. \ref{sec:build}, so it
501     should be straightforward. However, look at the provided concrete
502     implementations of actions if you need some example to setup your build.
503    
504     \section{How to build and use the library}
505     If the makefiles are correctly set up, the only remaining thing is to type
506     \verb1make all1. Remember to set the PAMELA environment with the set\_pam\_env
507     script BEFORE invoking \verb1make1. This will generate a {\it libPamCut.so} file
508     which will contain all the cuts. To clean the project and build from scratch
509     type \verb1make clean all1. To use the library in an analysis code the
510     environment header must be included in the code:
511     \verb1#include "<root PamCutdirectory>/PamCutEnv.h"1. With this, all the
512     classes and common definitions will be accessible. A typical usage of {\bf
513     PamCut} inside the analysis code would look like:
514    
515     \begin{verbatim}
516    
517     PamCutCollection collection;
518    
519     DummyCut1 dummy1;
520     collection.AddCut(dummy1);
521     DummyCut2 dummy2(param);
522     collection.AddCut(dummy2);
523    
524     collection.Process(event, 0, event->GetEntries()-1);
525    
526     \end{verbatim}
527    
528     In the simple example above a \verb1DummyCut11 and a \verb1DummyCut21 object
529     (which requires some sort of parameter) are instantiated. They are added to
530     \verb1collection1 which takes care of applying them to all the events.
531    
532     When the analysis code is compiled the linker must be aware that it
533     needs a library called {\it libPamCut.so} and where to find it. In the {\it
534     makefile} which builds the analysis program the following option must be added
535     to the linker invocation:
536     \newline
537     \verb1-L<root PamCut directory> -lPamCut1.
538    
539     One could also wish to move {\it libPamCut.so} to another directory: this path
540     must then replace what is indicated as \verb1<root PamCut directory>1 above.
541    
542     Finally, when the analysis code is compiled and linked against libPamCut.so, to
543     launch it it's necessary to tell the environment where the library is, so that
544     the program can dynamically access it at runtime. This information is encoded
545     in the environment variable LD\_LIBRARY\_PATH, which contains the paths of the
546     accessible libraries. If libPamCut.so is still in the root PamCut directory one
547     can type:
548     \newline
549     \verb1export LD_LIBRARY_PATH=<root PamCut directory>:$LD_LIBRARY_PATH1
550     \newline
551     This has to be done every time you open a shell; one way to avoid this is to
552     append the above line at the end of your set\_pam\_env script, so that it will
553     be automatically executed every time you set your PAMELA environment.
554    
555     \section{Usage summary}
556     Here's a short summary on how to develop a cut, build and use it. If one only
557     \begin{enumerate}
558     \item Obtain the code (from tarball, repository\ldots) and go in the root
559     code directory.
560     \item Check if the \verb1C++1 option in the Build section of {\it makefile}
561     is correctly set with the C++ compiler name present in your system (for many
562     Linux platform, \verb1g++1 is a safe choice).
563     \item Create a directory named as the cut class you want to develop.
564     \item Place inside the newly created directory a {\it .h} file and a {\it
565     .cpp} file, named as the direcory; edit the files to define and implement the
566     class (one can also cut and paste the files from an existing class and edit
567     them), defining at least the constructor, the distructor and {\bf Check} for
568     the new class.
569     \item Create inside the directory a {\it subdir.mk} file which contains the
570     instructions to build the directory content, as described in \ref{sec:build};
571     as usual, one can cut and paste from an existing class and then edit.
572     \item Modify the {\it makefile} in the root code directory as in
573     \ref{sec:build}, to include the newly developed cut.
574     \item Modify the {\it PamCutEnv.h} file, adding the \verb1#include#1 for the
575     new class header (see examples therein).
576     \item Set the PAMELA environment with the set\_pam\_env script.
577     \item Build the library typing \verb1make all1 (or \verb1make clean all1 to
578     build from scratch); this will produce the library {\it libPamCut.so} in the
579     root code directory, which will contain all the class definitions and
580     implementations.
581     \item Insert \verb1#include ``<root PamCut directory>/PamCutEnv.h#1 in the
582     analysis code, to have access to all the classes in the library.
583     \item Develop the analysis code
584     \end{enumerate}
585    
586     \section{Some advices and suggestions}
587     \begin{itemize}
588     \item Derive your cuts. Try to define a new class every time you need a new
589     cut, instead of modifying an existing one. As an example, you can define a
590     cut with a specific implementation for {\bf Check}, then derive from it many
591     classes which only redefine {\bf OnGood} and {\bf OnBad}. In this way, you
592     can have several post-selection options associated to the same cut; if
593     you'll ever need to modify the cut criteria, you will have to do it only in
594     one place, saving time and reducing code errors opportunities.
595     \item Be consistent with the existing code style. Everyone has its own
596     code style, with its own conventions for naming variables and functions based
597     on personal preferences. Maintaining a uniform code style is a good way to
598     improve the code readability, so it's worth a little effort. The conventions
599     chosen for {\bf PamCut} are:
600     \begin{itemize}
601     \item the names of private and protected members (variables and methods)
602     always begin with an underscore, eg., \verb1_previousOBT1, \verb1_LT1;
603     \item the names of variables usually begin with a lower case; for compound
604     words, the successive initials are upper case, eg., \verb1time1,
605     \verb1liveTime1, \verb1nHitPaddles1;
606     \item the names of classes and methods begin with upper case, eg.,
607     \verb1PamCut1, \verb1GeoFieldCut1, \verb1ApplyCut()1.
608     \end{itemize}
609     Within these conventions, a code row like:
610     \newline
611     \verb1 GeoFieldCut geoFieldCut;1
612     \newline
613     is easily interpreted as the instantiation of a class named
614     \verb1GeoFieldCut1 into an object named \verb1geoFieldCut1. This allows to
615     have objects whose names are almost identical to those of the respective
616     classes, allowing a straightforward type recognition. Also, the discrimination between
617     public and private variables and methods inside a class is immediate.
618     \item Respect the interface. {\bf PamCut} has been designed following precise
619     rules, which allow for a quite general environment that should cover many
620     of the necessities related to data analysis. Try to fit your
621     particular analysis in this scheme; this will result in a much more
622     raedable code. However, someone may need features that are not compatible with
623     the current interface. In this case, the first thing to do is to try a
624     workaround that would leave the interface unchanged. As an example, if the
625     automated post-selection tasks based on {\bf OnGood} and {\bf OnBad} does not
626     satisfy you, you can call directly the {\bf Check} method inside a loop and
627     then do a custom post-processing. In the worst case, the interface could
628     result incompatible with the analysis needs: in this case a redesign
629     hypotheses can be considered if the incompatibility is such that a large
630     piece of the analysis would be compromised. Redesigning is always a tricky
631     task, so it has to be considered as a last option.
632     \item Take care about other people. If you plan to write a code that is
633     likely to be used and modified by other people, please take your time to
634     write the documentation. Documenting the code is a boring and time-consuming
635     task, but can save you and your colleagues a lot of headaches and
636     misunderstandings. The better a code is documented, the lesser are the
637     questions other people will ask you.
638     \end{itemize}
639    
640    
641     \end{document}

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