fc2171bd4c
git-svn-id: https://svn.wxwidgets.org/svn/wx/wxWidgets/trunk@27090 c3d73ce0-8a6f-49c7-b76d-6d57e0e08775
204 lines
7.4 KiB
TeX
204 lines
7.4 KiB
TeX
\section{wxExpr overview}\label{exproverview}
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wxExpr is a C++ class reading and writing a subset of Prolog-like syntax,
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supporting objects attribute/value pairs.
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wxExpr can be used to develop programs with readable and
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robust data files. Within wxWidgets itself, it is used to parse
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the {\tt .wxr} dialog resource files.
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{\bf History of wxExpr}
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During the development of the tool Hardy within the AIAI, a need arose
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for a data file format for C++ that was easy for both humans and
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programs to read, was robust in the face of fast-moving software
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development, and that provided some compatibility with AI languages
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such as Prolog and LISP.
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The result was the wxExpr library (formerly called PrologIO), which is able to read and write a
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Prolog-like attribute-value syntax, and is additionally capable of
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writing LISP syntax for no extra programming effort. The advantages of
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such a library are as follows:
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\begin{enumerate}\itemsep=0pt
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\item The data files are readable by humans;
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\item I/O routines are easier to write and debug compared with using binary files;
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\item the files are robust: unrecognised data will just be ignored by the application
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\item Inbuilt hashing gives a random access capability, useful for when linking
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up C++ objects as data is read in;
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\item Prolog and LISP programs can load the files using a single command.
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\end{enumerate}
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The library was extended to use the ability to read and write
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Prolog-like structures for remote procedure call (RPC) communication.
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The next two sections outline the two main ways the library can be used.
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\subsection{wxExpr for data file manipulation}\itemsep=0pt
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The fact that the output is in Prolog syntax is irrelevant for most
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programmers, who just need a reasonable I/O facility. Typical output
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looks like this:
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\begin{verbatim}
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diagram_definition(type = "Spirit Belief Network").
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node_definition(type = "Model",
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image_type = "Diamond",
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attribute_for_label = "name",
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attribute_for_status_line = "label",
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colour = "CYAN",
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default_width = 120,
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default_height = 80,
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text_size = 10,
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can_resize = 1,
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has_hypertext_item = 1,
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attributes = ["name", "combining_function", "level_of_belief"]).
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arc_definition(type = "Potentially Confirming",
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image_type = "Spline",
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arrow_type = "End",
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line_style = "Solid",
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width = 1,
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segmentable = 0,
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attribute_for_label = "label",
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attribute_for_status_line = "label",
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colour = "BLACK",
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text_size = 10,
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has_hypertext_item = 1,
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can_connect_to = ["Evidence", "Cluster", "Model", "Evidence", "Evidence", "Cluster"],
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can_connect_from = ["Data", "Evidence", "Cluster", "Evidence", "Data", "Cluster"]).
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\end{verbatim}
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This is substantially easier to read and debug than a series of numbers and
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strings.
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Note the object-oriented style: a file comprises a series of {\it clauses}.
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Each clause is an object with a {\it functor}\/ or object name, followed
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by a list of attribute-value pairs enclosed in parentheses, and finished
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with a full stop. Each attribute value may be a string, a word (no quotes),
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an integer, a real number, or a list with potentially recursive elements.
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The way that the facility is used by an application to read in a file is
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as follows:
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\begin{enumerate}\itemsep=0pt
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\item The application creates a wxExprDatabase instance.
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\item The application tells the database to read in the entire file.
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\item The application searches the database for objects it requires,
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decomposing the objects using the wxExpr API. The database may be hashed,
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allowing rapid linking-up of application data.
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\item The application deletes or clears the wxExprDatabase.
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\end{enumerate}
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Writing a file is just as easy:
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\begin{enumerate}\itemsep=0pt
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\item The application creates a wxExprDatabase instance.
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\item The application adds objects to the database using the API.
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\item The application tells the database to write out the entire database,
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in Prolog or LISP notation.
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\item The application deletes or clears the wxExprDatabase.
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\end{enumerate}
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To use the library, include "wxexpr.h".
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\subsection{wxExpr compilation}
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For UNIX compilation, ensure that YACC and LEX or FLEX are on your system. Check that
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the makefile uses the correct programs: a common error is to compile
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y\_tab.c with a C++ compiler. Edit the CCLEX variable in make.env
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to specify a C compiler. Also, do not attempt to compile lex\_yy.c
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since it is included by y\_tab.c.
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For DOS compilation, the simplest thing is to copy dosyacc.c to y\_tab.c, and doslex.c to
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lex\_yy.c. It is y\_tab.c that must be compiled (lex\_yy.c is included by
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y\_tab.c) so if adding source files to a project file, ONLY add y\_tab.c
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plus the .cc files. If you wish to alter the parser, you will need YACC
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and FLEX on DOS.
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The DOS tools are available at the AIAI ftp site, in the tools directory. Note that
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for FLEX installation, you need to copy flex.skl into the directory
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c:/lib.
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If you are using Borland C++ and wish to regenerate lex\_yy.c and y\_tab.c
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you need to generate lex\_yy.c with FLEX and then comment out the `malloc' and `free'
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prototypes in lex\_yy.c. It will compile with lots of warnings. If you
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get an undefined \_PROIO\_YYWRAP symbol when you link, you need to remove
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USE\_DEFINE from the makefile and recompile. This is because the parser.y
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file has a choice of defining this symbol as a function or as a define,
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depending on what the version of FLEX expects. See the bottom of
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parser.y, and if necessary edit it to make it compile in the opposite
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way to the current compilation.
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%To test out wxExpr compile the test program (samples/wxexpr/wxexpr.exe),
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%and try loading test.exp into the test
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%program. Then save it to another file. If the second is identical to the
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%first, wxExpr is in a working state.
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\subsection{Bugs}
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These are the known bugs:
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\begin{enumerate}\itemsep=0pt
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\item Functors are permissible only in the main clause (object).
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Therefore nesting of structures must be done using lists, not predicates
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as in Prolog.
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\item There is a limit to the size of strings read in (about 5000 bytes).
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\end{enumerate}
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\subsection{Using wxExpr}
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This section is a brief introduction to using the wxExpr package.
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First, some terminology. A {\it wxExprDatabase}\/ is a list of {\it clauses},
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each of which represents an object or record which needs to be saved to a file.
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A clause has a {\it functor}\/ (name), and a list of attributes, each of which
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has a value. Attributes may take the following types of value: string, word,
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integer, floating point number, and list. A list can itself contain any
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type, allowing for nested data structures.
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Consider the following code.
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\begin{verbatim}
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wxExprDatabase db;
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wxExpr *my_clause = new wxExpr("object");
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my_clause->AddAttributeValue("id", (long)1);
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my_clause->AddAttributeValueString("name", "Julian Smart");
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db.Append(my_clause);
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ofstream file("my_file");
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db.Write(file);
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\end{verbatim}
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This creates a database, constructs a clause, adds it to the database,
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and writes the whole database to a file. The file it produces looks like
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this:
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\begin{verbatim}
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object(id = 1,
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name = "Julian Smart").
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\end{verbatim}
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To read the database back in, the following will work:
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\begin{verbatim}
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wxExprDatabase db;
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db.Read("my_file");
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db.BeginFind();
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wxExpr *my_clause = db.FindClauseByFunctor("object");
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int id = 0;
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wxString name = "None found";
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my_clause->GetAttributeValue("id", id);
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my_clause->GetAttributeValue("name", name);
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cout << "Id is " << id << ", name is " << name << "\n";
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\end{verbatim}
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Note the setting of defaults before attempting to retrieve attribute values,
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since they may not be found.
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