\section{How Builds Really Work and Even More Options}
\label{sec:builds_really_work_more_options}
+\index{build!more options}
This section describes how builds really work if you want to know more about making changes or understanding the process; probably only for a developer or system administrator.
\section{Configuration Features}
\label{sec:configuration_features}
+\index{build!configuration}
A listing of the current configuration features as of January 11, 2020:
\section{Thirdparty Parallel Build}
\label{sec:thirdparty_parallel_build}
+\index{build!thirdparty}
The Makefile in the thirdparty build directory employs a set of macros used to create a build rule set of thirdparty library build dependencies. The standard build sequence of [source, config, build] is used to prepare thirdparty products as static libraries. Build package dependency can be specified in the Makefile std-build macro call. These Makefile macro calls define the rules used for each thirdparty build. The expanded rule definitions may be viewed by using:
\section{Using the very latest Libraries}
\label{sec:latest_libraries}
+\index{build!use latest library}
Using the most current libraries can be a challenge for some of the Operating System distros that use
stable compilers, assemblers, and their own libraries. Because they are stable, they frequently do
\section{Find Lock Problems with Booby Trap}
\label{sec:find_lock_problems_booby_trap}
+\index{build!booby trap}
-A Booby Trap is used in CinGG for setting a trap to catch lock problems that might have been missed. It will trap boobies only if compile by adding \textit{-{}-with-booby} on the configuration command line. This is the default if you compile using \texttt{./bld.sh} from the GIT repository. It should not interfere with normal execution.
+A Booby Trap is used in \CGG{} for setting a trap to catch lock problems that might have been missed. It will trap boobies only if compile by adding \textit{-{}-with-booby} on the configuration command line. This is the default if you compile using \texttt{./bld.sh} from the GIT repository. It should not interfere with normal execution.
If you have the time and inclination, enable \textit{-{}-with-booby} and send any trap output that you find. Maybe you will catch some boobies and if you do, send a snapshot of any boobies you find.
\section{Valgrind Support Level}
\label{sec:valgrind_support_level}
+\index{build!valgrind}
Valgrind is a memory mis-management detector. It shows you memory leaks, deallocation errors, mismanaged threads, rogue reads/writes, etc. \CGG{} memory management is designed to work with Valgrind detection methods. This assists in developing reliable code. Use of Valgrind points out problems so that they can be fixed. For example, when this version of \CGG{} shuts down, it deallocates memory instead of just stopping, thus making memory leak detection possible.
This runs \CGG{} under the control of valgrind, and produces a log file in /tmp which will list information about any leaks, usually clearly identifiable. Be sure to Quit out of \CGG{} normally instead of Ctrl-C or a SEGV otherwise the program does not have a chance to cleanup and there will be some false alarms. But it runs very slowly, and is basically single threaded, which means that race conditions may be impossible to catch$\dots$ like one thread deletes memory that another thread is currently using. But overall it is a big help and if you test any new features, please email the log output. A lot of effort when writing the code was put into trying to be sure that all of the object constructors have matching destructors so that the leaks can be identified. There are already several libraries that create predictable memory leaks and valgrind does a good job for most of these.
-It is impossible to test everything with valgrind because some things are just too big and slow for a practical test. Occasionally you can find a leak or an illegal memory access. There are several false alarms that are difficult to avoid \textit{Conditional jump} messages, and \textit{unhandled DW\_OP\_}, but anything with the word \textit{illegal} in the message is important. Memory leaks that originate in \CGG{} are good to find and fix, but are usually not deadly.
+It is impossible to test everything with valgrind because some things are just too big and slow for a practical test. Occasionally you can find a leak or an illegal memory access. There are several false alarms that are difficult to avoid \textit{Conditional jump} messages, and \textit{unhandled DW\_OP\_}, but anything with the word \textit{illegal} in the message is important. Memory leaks that originate in \CGG{} are good to find and fix, but are usually not
+deadly. The listing of the memory leaks can be quite voluminous so locating the \textit{LEAK SUMMARY} section
+towards the end of the report is most useful.
+
\section{CFLAGS has -Wall}
\label{sec:cflags_has_-wall}
\section{Prof2 -- A Profiler}
\label{sec:prof2_profiler}
+\index{build!prof2}
Frequently there is a problem with a program running slow and you do not know why. You need a thumbnail analysis of where the program is spending most of its time without all of the overwhelming details. This is when a Profiler comes in handy.
Key in: \qquad \texttt{make clean all install}
-Later, if you wanttitle to remove this from the system,
+Because \textit{smap} may have to be found in the system if \textit{How to use} below does not work, you will have to do the following:
+\newline
+\newline
+Key in: \qquad \texttt{cp -a smap /usr/local/bin}
+
+
+Later, if you want to remove this from the system,
-key in: \qquad \texttt{make uninstall}
+Key in: \qquad \texttt{make uninstall}
\subsection{How to use}
\label{sub:how_to_use}
\textbf{10.200t 0.001u+0.000s 21.566r 47.3\%}\\
\textit{--- profile end ---}
-The summary line above in Bold represents the User time, System time, Real time and the percentage is how much Timer time elapsed over Real time so in this case the measurement covers 47.3\% of time.\\
+The summary line above in Bold represents the User time, System time, Real time and the percentage is how much Timer time elapsed over Real time so in this case the measurement covers 47.3\% of time.
+
So why use a Profiler? Because it is the ``ls'' for executable functions!!
+
+\section{How to Create a new Theme}
+\label{sec:how_create_theme}
+\index{theme!create new theme}
+
+A \textit{Theme} is a base class object that is created and customized as \textit{ThemeName}.
+It is constructed during program initialization in a theme plugin
+\texttt{PluginTClient},
+defined in \texttt{plugins/theme\_name} source directory.
+
+\texttt{theme\_name.C} and \texttt{theme\_name.h} are derived \textit{Theme} class object constructors.
+
+A \textit{Theme} is constructed during initialization in \texttt{init\_theme} (\texttt{mwindow.C}). The theme plugin is accessed using the \textit{name} from preferences and then the theme plugin is loaded which contains the code to construct the theme. A \textit{Theme} object has functions and data that \CGG{} uses to do a variety of customizations, such as \texttt{default\_window\_positions}, and it can modify GUI defaults like \\
+\texttt{default\_text\_color} when it is initialized.
+
+The theme plugin contains a \textit{new\_theme} function that allocates and constructs a
+\textit{ThemeName} object with base classes of \textit{BC\_Theme} (gui setup), \textit{Theme} (\CGG{} defaults), and \textit{ThemeName}, with definitions and overrides that create the custom theme. To create a new theme, a new plugin is needed:
+
+\begin{lstlisting}[numbers=none]
+ #include "header files.h"
+ PluginClient* new_plugin(PluginServer *server)
+ {
+ return new NameMain(server);
+ }
+
+ NameMain::NameMain(PluginServer *server)
+ : PluginTClient(server)
+ {
+ }
+
+ NameMain::~NameMain()
+ {
+ }
+ const char* NameMain::plugin_title() { return N_("Name"); }
+
+ Theme* NameMain::new_theme()
+ {
+ theme = new ThemeName;
+ extern unsigned char _binary_theme_name_data_start[];
+ theme->set_data(_binary_theme_name_data_start);
+ return theme;
+ }
+
+ Name::Name()
+ : Theme()
+ {
+ }
+
+ Name::~Name()
+ {
+ delete stuff;
+ }
+\end{lstlisting}
+
+When a theme is constructed by \texttt{NameMain::new\_theme()}, it sets a pointer to a
+block of data created in the plugin build that contains all of the png data
+files in the \texttt{plugins/theme\_name/data} directory. These images may define or override the appearance of gui images, such as \textit{ok.png} (the ok button). There are usually a large number of images that need to be defined. The theme plugin adds them to the theme image data in the \texttt{theme $\rightarrow$ initialize()} function. The best list of theme image setup is probably in SUV (\texttt{plugins/theme\_suv/suv}).
+
+The easy way to create a new theme is to copy an existing theme and change
+its name to \textit{ThemeName}, change \texttt{plugin\_title()} to the new name, and then tweak the definitions until you are happy with the results. The file
+names and Makefile also need to be updated to the new theme name. The source
+can by manually rebuilt by invoking \textit{make} in the \texttt{plugins/theme\_name}
+directory.
+
+Once the new theme is built into the plugin library, it will automatically be discovered by the plugin probe
+and it will become an available theme in \textit{Preferences}.
+
+If you are ready to add it to the main build, then \textit{theme\_name} should be
+included in the DIRS targets of the \texttt{plugins/Makefile}, and \texttt{plugin\_defs} needs \textit{theme\_name} in the themes list.
+
+Themes usually require considerable time to create from scratch. For
+example, the SUV theme has over 800 lines in the initialize function, and has over
+500 png images in the data directory. Most of these images and data values are
+required to be initialized by the custom theme constructor; very tedious and
+time consuming work. Creating a new theme is usually a lot of work.
projects / goodguy / cin-manual-latex.git / blobdiff