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tconfpy / tconfpy.3
.ds CP 2003-2004
.ds TC \'tconfpy\'
.TH TCONFPY 3 "TundraWare Inc."

.SH NAME tconfpy.py
 Configuration File Support For Python Applications

.SH SYNOPSIS

It is common to provide an external "configuration file" when writing
sophisticated applications.  This gives the end-user the ability to
easily change program options by editing that file.

\*(TC is a Python module for parsing such configuration files. \*(TC
understands and parses a configuration "language" which has a rich set
of string-substitution, variable name, conditional, and validation
features.

By using \*(TC, you unburden your program from the major responsibility
of configuration file parsing and validation, while providing your
users a rich set of configuration features.

.SH DOCUMENT ORGANIZATION

This document is divided into 4 major sections: 


.B PROGRAMMING USING THE \*(TC API
discusses how to call the configuration file parser, the options
available when doing this, and what the parser returns.  This is
the "Programmer's View" of the module and provides in-depth
descriptions of the API, data structures, and options available to
the programmer.

.B CONFIGURATION LANGUAGE REFERENCE
describes the syntax and semantics of the configuration language
recognized by \*(TC.  This is the "User's View" of the package, but
both programmers and people writing configuration files will find this
helpful.

.B ADVANCED TOPICS
describes some ways to combine the various \*(TC features to
do some fairly nifty things.

.B INSTALLATION
explains how to install this package on various platforms.  This
information can also be found in the \'READ-1ST.txt\' file distributed
with the package.


.SH PROGRAMMING USING THE \*(TC API

\*(TC is a Python module and thus available for use by any Python
program.  This section discusses how to invoke the \*(TC parser, the
options available when doing so, and what the parser returns to
the calling program.

One small note is in order here.  As a matter of coding style and
brevity, the code examples here assume the following Python import
syntax:

.nf
    from tconfpy import *
.fi

If you prefer the more pedestrian:

.nf
    import tconfpy
.fi

you will have to prepend all references to a \*(TC object with
\'tconfpy.\'.  So \'retval=ParseConfig(...\' becomes
\'retval = tconfpy.ParseConfig(...\' and so on.

You will also find the test driver code provided in the \*(TC package
helpful as you read through the following sections.  \'test-tc.py\' is
a utility to help you learn and exercise the \*(TC API.  Perusing the
code therein is helpful as an example of the topics discussed below.


.SS API Overview
The \*(TC API consists of a single call.  Only the configuration file
to be processed is a required parameter, all the others are optional
and default as described below:    

.nf
    from tconfpy import *

    retval = ParseConfig(cfgfile,
                         InitialSymTable={},
                         AllowNewVars=True,
                         AllowNewNamespaces=True,
                         LiteralVars=False,
                         Debug=False
                        )

where:

.fi

.TP
.B cfgfile   (Required Parameter - No Default)


The the name of a file containing configuration information

.TP
.B InitialSymTable   (Default: {})


A pre-populated symbol table (a Python dictionary).  As described
below, this must contain valid \'VarDescriptor\' entries for each
symbol in the table.

.TP
.B AllowNewVars   (Default: True)


Allow the user to create new variables in the configuration file.

.TP
.B AllowNewNamespaces   (Default: True)


Allow new namespaces to be created in the configuration file.

.TP
.B LiteralVars   (Default: False)


If set to True this option enables variable substitutions within
\'.literal\' blocks of a configuration file.  See the section in the
language reference below on \'.literal\' usage for details.

.TP
.B Debug   (Default: False)


If set to True, \*(TC will provide detailed debugging information
about each line processed when it returns.

.TP
.B retval


An object of type \'tconfpy.RetObj\' used to return parsing results.


.SS The Initial Symbol Table API Option

The simplest way to parse a configuration file is just to call
the parser with the name of that file:


.nf
    retval = ParseConfig("MyConfigFile")
.fi

Assuming your configuration file is valid, \'ParseConfig()\' will
return a symbol table populated with all the variables defined in the
file and their associated values. This symbol table will have
.B only
the symbols defined in that file (plus a few built-in and pre-defined
symbols needed internally by \*(TC).

However, the API provides a way for you to pass a "primed" symbol
table to the parser that contains pre-defined symbols/values of
your own choosing.  Why on earth would you want to do this?  There
are a number of reasons:


.IP \(bu 4
You may wish to write a configuration file which somehow depends
on a pre-defined variable that only the calling program can know:

.nf
    .if [APPVERSION] == 1.0
         # Set configuration for older application releases
    .else
         # Set configuration for newer releases
    .endif
.fi

In this example, only the calling application can know its own
version, so it sets the variable APPVERSION in a symbol table
which is passed to \'ParseConfig()\'.

.IP \(bu 4
You may wish to "protect" certain variable names be creating
them ahead of time and marking them as "Read Only".  This is
useful when you want a variable to be available for use
within a configuration file, but you do not want users to
be able to change its value.  In this case, the variable can
be referenced in a string substitution or conditional test,
but cannot be changed.

.IP \(bu 4
You may want to place limits on what values can be assigned to
a particular variable.  When a variable is newly defined in a
a configuration file, it just defaults to being a string 
variable without any limits on its length or content.   But 
variables that are created by a program have access to the
variable's "descriptor".  By setting various attribues
of the variable descriptor you can control variable type,
content, and range of values.  In other words, you can have
\*(TC "validate" what values the user assigns to particular
variables.  This substantially simplifies your application because
no invalid variable value will ever be returned from the parser.


.SS How To Create An Initial Symbol Table

A \*(TC "Symbol Table" is really nothing more than a Python
dictionary.  The key for each dictionary entry is the variable's name
and the value is a \*(TC-specific object called a "variable
descriptor".  Creating new variables in the symbol table involves
nothing more than this:

.nf
    
    from tconfpy import *
    
    # Create an empty symbol table
    MySymTable = {}
     
    # Create descriptor for new variable
    MyVarDes = VarDescriptor()
    
    # Code to fiddle with descriptor contents goes here
    MyVarDes.Value = "MyVal"

    # Now load the variable into the symbol table
    MySymTable["MyVariableName"] = MyVarDes

    # Repeat this process for all variables, then call the parser

    retval = ParseConfig("MyConfigFile", InitialSymTable=MySymTable)

.fi


The heart of this whole business the \'VarDescriptor\' object.  It
"describes" the value and properties of a variable.  These
descriptor objects have the following attributes and defaults:

.nf
  
    VarDescriptor.Value     = ""
    VarDescriptor.Writeable = True
    VarDescriptor.Type      = TYPE_STRING
    VarDescriptor.Default   = ""
    VarDescriptor.LegalVals = []
    VarDescriptor.Min       = None
    VarDescriptor.Max       = None
.fi

When \*(TC encounters a new variable in a configuration file, it just
instantiates one of these descriptor objects with these defaults for
that variable.  That is, variables newly-defined in a configuration
file are entered into the symbol table as string types, with an
initial value of "" and with no restriction on content or length.

But, when you create variables under program control to "prime" an
initial symbol table, you can modify the content of any of these
attributes for each variable.  These descriptor attributes are what
\*(TC uses to validate subsequent attempts to change the variable's
value in the configuration file.  In other words, modifying a
variable's descriptor tells \*(TC just what you'll accept as "legal"
values for that variable.

Each attribute has a specific role:

.TP
.B VarDescriptor.Value       (Default: Empty String)

Holds the current value for the variable.

.TP
.B VarDescriptor.Writeable   (Default: True)

Sets whether or not the user can change the variable's value.  Setting
this attribute to False makes the variable 
.B Read Only.

.TP
.B VarDescriptor.Type        (Default: TYPE_STRING)

One of TYPE_BOOL, TYPE_COMPLEX, TYPE_FLOAT, TYPE_INT, or TYPE_STRING.
This defines the type of the variable.  Each time \*(TC sees 
a value being assigned to a variable in the configuration file, it
checks to see if that variable already exists in the symbol table.
If it does, the parser checks the value being assigned and makes sure
it matches the type declared for that variable.  For example,
suppose you did this when defining the variable, \'foo\':

.nf
    VarDescriptor.Type = TYPE_INT
.fi

Now suppose the user puts this in the configuration file:

.nf
    foo = bar
.fi

This will cause a type mismatch error because \'bar\' cannot be coerced
into an integer type - it is a string.


As a general matter, for existing variables, \*(TC attempts to coerce
the right-hand-side of an assignment to the type declared for that
variable.  The least fussy operation here is when the variable is
defined as TYPE_STRING because pretty much everything can be coerced
into a string.  For example, here is how \'foo = 3+8j\' is treated for
different type declarations:


.nf

VarDescriptor.Type        VarDescriptor.Value
------------------        -------------------

TYPE_BOOL                 Type Error
TYPE_COMPLEX              3+8j         (A complex number)
TYPE_FLOAT                Type Error
TYPE_INT                  Type Error
TYPE_STRING               \'3+8j\'     (A string)
.fi

This is why the default type for newly-defined variables in
the configuration file is TYPE_STRING: they can accept
pretty much
.B any
value.

.TP
.B VarDescriptor.Default     (Default: Empty String)

This is a place to store the default value for a given variable.  When
a variable is newly-defined in a configuration file, \*(TC places the
first value assigned to that variable into this attribute.  For
variables already in the symbol table, \*TC does nothing to this
attribute.  This attribute is not actually used by \*(TC for anything.
It is provided as a convenience so that the calling program can easily
"reset" every variable to its default value if desired.

.TP
.B VarDescriptor.LegalVals   (Default: [])

Sometimes you want to limit a variable to a specific set of values.
That's what this attribute is for.  \'LegalVals\' explictly lists
every legal value for the variable in question.  If the list is
empty,then this validation check is skipped.

The exact semantics of LegalVals varies depending on
the type of the variable.

.nf

Variable Type                What LegalVals Does
-------------                -------------------
Boolean                      Nothing - Ignored

Integer, Float, Complex      List of numeric values the
                             user can assign to this variable

                             Examples: [1, 2, 34]
                                       [3.14, 2.73, 6.023e23]
                                       [3.8-4j, 5+8j]

String                       List of Python regular expressions.
                             User must assign a value to this
                             variable that matches at least
                             one of these regular expressions.

                             Example:   [r'a+.*', r'^AnExactString$']
.fi

The general semantic here is "If Legal Vals is not an empty list, the
user must assign a value that matches one of the items in LegalVals."

One special note applies to \'LegalVals\' for string variables.  \*(TC
always assumes that this list contains Python regular expressions.
For validation, it grabs each entry in the list, attempts to compile
it as a regex, and checks to see if the value the user wants to set
matches.  If you define an illegal regular expression here, \*(TC will
catch it and produce an appropriate error.


.TP
.B VarDescriptor.Min and VarDescriptor.Max  (Default: None)

These set the minimum and maxium legal values for the variables,
but the semantics vary by variable type:

.nf

Variable Type               What Min/Max Do
-------------               ---------------

Boolean, Complex            Nothing - Ignored

Integer, Float              Set Minimum/Maxium allowed values.

String                      Set Minimum/Maximum string length

.fi

In all cases, if you want these tests skipped, set \'Min\' or \'Max\'
to the Python None.

.P
All these various validations are logically "ANDed" together.
i.e., A new value for a variable must be allowed 
AND of the appropriate type AND one of the legal values AND
within the min/max range.

\*(TC makes no attempt to harmonize these validation
conditions with each other.  If you specify a value in
\'LegalVals\' that is, say, lower than allowed by
\'Min\' you will always get an error when the user sets
the variable to that value: It passed the \'LegalVals\'
validation but failed it for \'Min\'.


.SS Some Notes On Boolean Variables

One last note here concerns Boolean variables.  Booleans are actually
stored in the symbol table as the Python values, True or False.
However, \*(TC accepts user statements that set the value of the
boolean in a number of formats:

.nf

Boolean True              Boolean False
------------              -------------

foo = 1                   foo = 0
foo = True                foo = False
foo = Yes                 foo = No
foo = On                  foo = Off 

.fi

This is the one case where \*(TC is insensitive to case -
"tRUE", "TRUE", and "true" are all accepted, for example.

.B NOTE HOWEVER:
If the user wants to do a conditional test on the value of
a boolean they
.B must
observe case and test for either \'True\' or \'False\':

.nf

    .if [boolvar] != False    # This works fine

    .if [boolvar] != FALSE    # This does not work - Case is not being observed

    .if [boolvar] != Off      # Neither does this - Only True and False can be tested

.fi


.SS The Initial Symbol Table And Lexical Namespaces

The
.B CONFIGURATION LANGUAGE REFERENCE
section below discusses lexical namespaces in some detail from the
user's point-of-view.  However, it is useful for the programmer
to understand how they are implemented. 

\*(TC is written to use a pre-defined variable named \'NAMESPACE\' as
the place where the current namespace is kept.  If you do not
define this variable in the initial symbol table passed to the parser,
\*(TC will create it automatically with an initial value of "".

From a programmer's perspective, there are are few important things
to know about namespaces and the \'NAMESPACE\' variable:


.IP \(bu 4
You can manually set the initial namespace to something other than
"".  You do this  by creating the \'NAMESPACE\' variable in the initial
symbol table passed to the parser, and setting the \'Value\' attribute
of its descriptor to whatever you want as the initial namespace.

.IP \(bu 4
Each time the user enters a new namespace, it is added to the
\'LegalVals\' attribute of the \'NAMESPACE\' variable descriptor.
This is done to keep a "history" of all namespaces encountered during
parsing.

.IP \(bu 4
If you are inhibiting the creation of new namespaces (via the
\'AllowNewNamespaces = False\' option described below) you can
enumerate the namespaces the user
.B is
allowed to use by pre-defining them.  You do this by adding each
permitted namespace to the \'LegalVals\' attribute of the
\'NAMESPACE\' variable descriptor in the initial symbol table.

.IP \(bu 4
When the call to \'ParseConfig()\' completes, the \'Value\'
attribute of the \'NAMESPACE\' variable descriptor will contain
the namespace that was in effect when the parse completed.  i.e.,
It will contain the last namespace used.

.IP \(bu 4
Similarly, on parser completion, the \'LegalVals\' attribute of the
\'NAMESPACE\' variable descriptor will contain the name of all the
namespaces encountered during parsing.  This is
.B not
true if you suppressed new namespace creation with the
\'AllowNewNamespaces = False\' API option.  In that case, the
\'LegalVals\' attribute will contain only those namespaces you
pre-defined.  All of these may- or may not have been used in the
configuration file, there is no way to tell.


.SS How The  \*(TC Parser Validates The Initial Symbol Table

When you pass an initial symbol table to the parser, \*(TC does some
basic validation that the table contents properly conform to the
\'VarDescriptor\' format and generates error messages if it finds
problems.  However, the program does
.B not
check your specifications to see if they make sense.  For instance
if you define an integer with a minimum value of 100 and a maximum
value of 50, \*(TC cheerfully accepts these limits even they they
are impossible.  You'll just be unable to do anything with that
variable - any attempt to change its value will cause an error
to be recorded.  Similarly, if you put a value in \'LegalVals\' that
is outside the range of \'Min\' to \'Max\', \*(TC will accept
it quietly.

.SS The \'AllowNewVars\' API Option

By default, \*(TC lets the user define any new variables they
wish in a configuration file, merely by placing a line in the
file in this form:

.nf
    Varname = Value
.fi

However, you can disable this capability by calling the parser like
this:

.nf
    retval = ParseConfig("myconfigfile", AllowNewVars=False)
.fi

This means that the configuration file can "reference"
any pre-defined variables, and even change their values
(if they are not Read-Only), but it cannot create
.B new
variables.  

This feature is primarily intended for use when you pass an initial
symbol table to the parser and you do not want any other variables
defined by the user.  Why?  There are several possible uses for
this option:

.IP \(bu 4
You know every configuration variable name the calling program 
will use ahead of time.  Disabling new variable names keeps
the configuration file from getting cluttered with variables
that the calling program will ignore anyway, thereby
keeping the file more readable.

.IP \(bu 4
You want to insulate your user from silent errors caused
by misspellings.  Say your program looks for a configuration
variable called \'MyEmail\' but the user enters something
like \'myemail = foo@bar.com\'.  \'MyEmail\' and \'myemail\'
are entirely different variables and only the former is
recognized by your calling program.  By turning off new
variable creation, the user's inadvertent misspelling of
the desired variable name will be flagged as an error.

Note, however, that there is one big drawback to disabling new
variable creation.  \*(TC processes the configuration file on a
line-by-line basis.  No line "continuation" is supported.  For really
long variable values and ease of maintenance, it is sometimes helpful
to create "intermediate" variables what hold temporary values used to
construct a variable actually needed by the calling program.  For
example:

.nf

    inter1 = Really, really, really, really, long argument #1
    inter2 = Really, really, really, really, long argument #2

    realvar = command [inter1] [inter2]
.fi

If you disable new variable creation you can't do this
anymore unless all the variables \'inter1\', \'inter2\',
and \'realvar\' are pre-defined in the initial symbol
table passed to the parser.


.SS The \'AllowNewNamespaces\' API Option

By default, \*(TC supports the use of an arbitrary number of
lexical namespaces.  They can be pre-defined in an initial
symbol table passed to the parser and/or created in the configuration
file as desired.  (The details are described in a later section
of this document.)

There may be times, however, when you do not want users creating new
namespaces on their own.  The reasons are much the same as for 
preventing the creation of new variables in the option above:
Maintaining simplicity and clarity in the configuration file and
preventing "silent" errors due to misspellings.

In this case, call the API with \'AllowNewNamespaces=False\' and the
creation of new namespaces in the configuration file will be disabled.
Any attempt to create a new namespaces via either the
\'[new-ns-name]\' or \'NAMESPACE=new-ns-name\' methods will cause a
parse error to be generated.

It is important to realize that this option only disables the
creation of
.B new
namespaces.  As discussed in the previous section on namespace
processing, it is possible to pass an initial symbol table to the
parser which has one or more pre-defined namespaces in it.  Each of
these pre-defined namespaces is available for use throughout the
configuration file even if \'AllowNewNamespaces\' is set to False.


.SS The \'LiteralVars\' API Option

\*(TC supports the inclusion of literal text anywhere in a
configuration file via the \'.literal\' directive.  This
directive effectively tells the \*(TC parser to pass
every line it encounters "literally" until it sees a
corresponding \'.endlinteral\' directive.   By default,
\*(TC does
.B exactly
this.  However, \*(TC has very powerful variable substitution
mechanisms.  You may want to embed variable references in a
"literal" block and have them replaced by \*(TC.

Here is an example:

.nf
    MyEmail = me@here.com   # This defines variable MyEmail

    .literal
        printf("[MyEmail]");  /* A C Statement */
    .endliteral
.fi

By default, \'ParseConfig()\' will leave everything within
the \'.literal\'/\'.endliteral\' block unchanged.  In our
example, the string:

.nf
    printf("[MyEmail]");  /* A C Statement */
.fi

would be in the list of literals returned by \'ParseConfig()\'.

However, we can ask \*(TC to do variable replacement
.B within
literal blocks by setting \'LiteralVars=True\' in the
\'ParseConfig()\' call:

.nf
    retval = ParseConfig("myconfigfile", LiteralVars=True)
.fi


In this example, \*(TC would return:

.nf
    printf("me@here.com");  /* A C Statement */
.fi

At first glance this seems only mildly useful, but it is
actually very handy.  As described later in this document,
\*(TC has a rich set of conditional operators and string
sustitution facilities.  You can use these features along
with literal block processing and variable substitution
within those blocks.  This effectively lets you use
\*(TC as a preprocessor for
.B any
other language or text.



.SS The \'Debug\' API Option

\*(TC has a fairly rich set of debugging features built into its
parser.  It can provide some detail about each line parsed as well
as overall information about the parse.  Be default, debugging is
turned off.  To enable debugging, merely set \'Debug=True' in the
API call:

.nf
    retval = ParseConfig("myconfigfile", Debug=True)
.fi

.SS How \*(TC Processes Errors

As a general matter, when \*(TC encounters an error in the
configuration file currently being parsed, it does two things.  First,
it adds a descriptive error message into the list of errors returned
to the calling program (see the next section).  Secondly, in many
cases, noteably during conditional processing, it sets the parser
state so the block in which the error occurred is logically False.
This does not happen in every case, however.  If you are having
problems with errors, enable the Debugging features of the package and
look at the debug output.  It provides detailed information about what
caused the error and why.


.SS \*(TC Return Values

When \*(TC is finished processing the configuration file it returns an
object which contains the entire results of the parse.  This includes
a symbol table, any relevant error or warning messages, debug information
(if you requested this via the API), and any "literal" lines encountred
in the configuration.

The return object is an instance of the class \'twander.RetObj\' which is
nothing more than a container to hold return data.  In the simplest
case, we can parse and extract results like this:

.nf
    from tconfpy import *

    retval = ParseConfig("myconfigfile", Debug=True)
.fi

\'retval\' now contains the results of the parse:

.TP
.B retval.Errors
A Python list containing error messages.  If this list is empty, you
can infer that there were no parsing errors - i.e., The configuration
file was OK.

.TP
.B retval.Warnings
A Python list containing warning messages.  These describe minor
problems not fatal to the parse process, but that you really ought to
clean up in the configuration file.


.TP
.B retval.SymTable

A Python dictionary which lists all the defined symbols and their
associated values.  A "value" in this case is always an object of type
tconfpy.VarDescriptor (as described above).

.TP
.B retval.Literals

As described below, the \*(TC configuration language supports a
\'.literal\' directive.  This directive allows the user to embed
literal text anywhere in the configuration file.  This effectively
makes \*(TC useful as a preprocessor for any other language or text.
retval.Literals is a Python list containing all literal text
discovered during the parse.

.TP
.B retval.Debug

A Python list containing detailed debug information for each line
parsed as well as some brief summary information about the parse.
retval.Debug defaults to an empty list and is only populated if you
set \'Debug=True\' in the API call that initiated the parse (as in the
example above).


.SH CONFIGURATION LANGUAGE REFERENCE


\*(TC recognizes a full-featured configuration language that includes
variable creation and value assignment, a full preprocessor with
conditionals, type and value enforcement, and lexical namespaces.
This section of the document describes that language and provides
examples of how each feature can be used.

.SS \*(TC Configuration Language Syntax

\*(TC supports a fairly simple and direct configuration
language syntax:


.IP \(bu 4
Each line is treated independently.  There is no line
"continuation".

.IP \(bu 4
The \'#'\ can begin a comment anywhere on a line.  This is done
blindly.  If you need to embed this symbol somewhere within a variable
value, use the \'[HASH]\' variable reference.

.IP \(bu 4
Whitespace is (mostly) insignificant.  Leading and trailing
whitespace is ignored, as is whitespace around comparison
operators.  However, there are some places where
whitespace matters:

.nf
    - Variable names may not contain whitespace

    - Directives must be followed by whitespace if they 
      take other arguments.

    - When assigning a value to a string variable, 
      whitespace within the value on the right-hand-side
      is preserved.  Leading- and trailing whitespace around
      the right-hand-side of the assignment is ignored.

    - Whitespace within both the left- and right-hand-side
      arguments of a conditional comparison 
      (\'.if ... == / != ...\') is significant for purposes
      of the comparison.
.fi

.IP \(bu 4
Case is always significant except when assigning a value to Booleans
(described in the previous section).

.IP \(bu 4
Regardless of a variable's type, all variable references
return
.B a string representation of the variable's value!
This is done so that the variable's value can be used for comparison
testing and string substitution/concatenation.  In other words,
variables are stored in their native type in the symbol table that is
returned to the calling program.  However, they are treated as strings
during the parsing of the configuration file whenever they are used in
a comparison test or in a substitution.

.IP \(bu 4
Any line which does not conform to these rules and/or is not
in the proper format for one of the operations described below,
is considered an error.


.SS Creating Variables And Assigning A Value

The heart of a configuration file is a "variable".  Variables are
stored in a "Symbol Table" which is returned to the calling program
once the configuration file has been processed.  The calling program
can pre-define any variables it wishes before processing a
configuration file.  You can normally also define your own new
variables in the configuration file as desired (unless the programmer
has inhibited new variable creation).

Variables are assigned values like this:

.nf
    MyVariable = Some string of text
.fi

If \'MyVariable\' is a new variable, \*(TC will create it on the spot.
If it already exists, \*(TC will first check and make sure that \'Some
string of text\' is a legal value for this variable.  If not, it will
produce an error and refuse to change the current value of
\'MyVariable\'.

Anytime you create a new variable, the first value assigned to
it is also considered its "default" value.  This may (or may
not) be meaningful to the application program.

Variables which are newly-defined in a configuration file are
always understood to be
.B string
variables - i.e., They hold "strings" of text.  However, it is
possible for the applications programmer to pre-define
variables with other types and place limitations on what values
the variable can take and/or how short or long a string variable
may be.  (See the previous section,
.B PROGRAMMING USING THE \*(TC API
for all the gory details.)


.SS Variable Names

Variables can be named pretty much anything you like, with certain
restrictions:

.IP \(bu 4
Variable names may not contain whitespace.

.IP \(bu 4
Variable names may not begin with \'$\'.  The one exception
to this is when you are referencing the value of an environment
variable as just described.

.IP \(bu 4
Variable names cannot have the \'#\' character anywhere in them
because \*(TC sees that character as the beginning a comment.

.IP \(bu 4
Variable names cannot begin with \'.\' character.  \*(TC understands
a leading period in a variable name to be a "namespace escape".
This is discussed in a later section on lexical namespaces.

.IP \(bu 4
You cannot have a variable whose name is the empty string.  This is
illegal:

.nf
     = String
.fi

.IP \(bu 4
The variable named \'NAMESPACE\' is not available for your own
use.  \*(TC understands this variable to hold the current lexical
namespace as described later in this document.  If you set it
to a new value, it will change the namespace, so be sure this is
what you wanted to do.


.SS Getting And Using The Value Of A Variable

You can get the value of any currently defined variable by
"referencing" it like this:

.nf
    .... [MyVariable] ...
.fi

The brackets surrounding any name are what indicate that you want that
variable's value.

You can also get the value of any Environment Variable on your
system by naming the variable with a leading \'$\':

.nf
    ... [$USER] ...   # Gets the value of the USER environment variable
.fi

However you cannot set the value of an environment variable:

.nf
    $USER = me   # This is not permitted
.fi


This ability to both set and retrieve variable content makes it easy
to combine variables through "substitution":

.nf

    MYNAME = Mr. Tconfpy
    MYAGE  = 101

    Greeting = Hello [MYNAME], you look great for someone [MYAGE]!

.fi


Several observations are worth noting here:

.IP \(bu 4
The substitution of variables takes place as soon as the parser
processes the line \'Greeting = ...\'.  That is, variable substitution
happens as it is encountered in the configuration file.  The only
exception to this is if an attempt is made to refer to an
undefined/non-existent variable.  This generates an error.

.IP \(bu 4
The variable \'Greeting\' now contains the
.B string
"Hello Mr. Tconfpy, you look great for someone 101!"   This is true even
if variable \'MYAGE\' has been defined by the calling program to be
an integer type.  To repeat a previously-made point:  All variable substitution
and comparison operations in a configuration file are done with
.B strings
regardless of the actual type of the variables involved.


.IP \(bu 4
Unless a variable as been marked as "Read Only" by the application
program, you can continue to change its value as you go.  Simply
adding another line at the end of our example above will change the
value of \'Greeting\' to something new:

.nf
    Greeting = Generic Greeting Message
.fi

In other words, the last assignment statement for a given variable
"wins".  This may seem sort of pointless, but it actually has great
utility.  You can use the \'.include\' directive to get, say, a
"standard" configuration provided by the system administrator for a
particular application.  You can then selectively override the
variables you want to change in your own configuration file.

.SS Indirect Variable Assignment

The dereferencing of a variable's value can take place on either
the right- or
.B left-hand-side
of an assignment statement.  This means so-called "indirect"
variable assignments are permitted:

.nf
     CurrentTask    = HouseCleaning
     [CurrentTask]  = Dad
.fi

To understand what this does you need to realize that before
\*(TC does anything with a statement in a configuration file, it
replaces every variable reference with its associated value
(or produces an error for references to non-existent variables).
So the second statement above is first converted to:

.nf
    HouseCleaning = Dad
.fi

i.e., The value \'Dad\' is assigned to a (new) variable called
\'HouseCleaning\'.  In other words, putting a variable reference
on the left-hand-side of an assignment like this allows you
to access another variable which is named "indirectly".  You have
to be careful when doing this, though.  Consider a similar, but
slightly different example:

.nf
     CurrentTask    = House Cleaning   # This is fine
     [CurrentTask]  = Dad              # Bad!
.fi

The reason this no longer works is that the indirect
reference causes the second line to parse to:

.nf
    House Cleaning = Dad
.fi

This is illegal because whitespace is not permitted in variable names.
\*(TC will produce an error if it sees such a construct.

If you get into the habit of reading \'[something]\' as,
"The current value of \'something\'" this whole area of variable
naming and referencing will be easier to keep clear in your
thinking.  See if you understand what the following does
(if you don't, try it out with \'test-tc.py\'):

.nf
    foo   = 1  
    bar   = 2
    [foo] = bar
    [bar] = [foo]
.fi

You can get pretty creative with this since variable references
can occur pretty much anywhere in an assignment statement.
The only place they cannot appear is
.B within
another variable reference.  That is, you cannot "nest" references:

.nf
    # The Following Is Fine

    FOO          = Goodness
    BAR          = Me
    Oh[FOO][BAR] = Goodness Gracious Me!

    # But This Does NOT Do What You Might Think

    [FOO[BAR]] = Something Or Other  # Avoid nested constructs like this!
.fi

.SS Lexical Namespaces

The discussion of variable assignment and reference needs to be
expanded now to include the idea of "lexical namespaces".  Think of a
namespace as just being the current context for variables - a way to
group variables together.  The idea is that a variable name or
reference is always relative to the current namespace.  That is, the
"real" name of the variable is the concatenation of the current
namespace with the variable's name.

For instance, suppose the current namespace is "MYNS" and we see the
following in a configuration file:

.nf
    Foo = Bar
    Baz = [Foo]
.fi

What this
.B really
means to \*(TC is this:

.nf
    MYNS.Foo = MYNS.Bar
    MYNS.Baz = [MYNS.Foo]
.fi

In other words, \*(TC always prepends the current namespace (plus a
separating period) to any variable assignment or reference it finds in
a configuration.  The one exception is when the namespace is "", in
which case \*(TC does not add anything to the variable names.

By default, the initial namespace is always "", but you can change this
as desired.  Note, however, that the programmer can change this default
initial namespace if they wish.  Also there is a programming option
(\'AllowNewNamespaces\', described in the previous section) which can limit
you to using only the namespaces the programmer has pre-defined.  i.e., You
will not be able to create 
.B new
namespaces of your own invention.

You can change to a new namespace anytime within the configuration file
a number of ways:


So how do you access variables in a namespace different than the one
you are in currently?


What's the point of all this namespace business anyway?


.SS Pre-Defined Variables

.SS The \'.include\' Directive

.SS Conditional Directives

.SS \'.literal\. - Using \*(TC As A Preprocessor For Other Languages

.SS Type And Value Enforcement

.SH ADVANCED TOPICS

.SS Guaranteeing A Correct Base Configuration

.SS Enforcing Mandatory Configurations

.SS Iterative Parsing


.SH INSTALLATION

There are three ways to install \*(TC depending on your preferences
and type of system.  In each of these installation methods you must be
logged in with root authority on Unix-like systems or as the
Administrator on Win32 systems.


.SS Preparation - Getting And Extracting The Package


For the first two installation methods, you must first download the
latest release from:

.nf
    http://www.tundraware.com/Software/tconfpy/
.fi

Then unpack the contents by issuing the following command:

.nf
    tar -xzvf py-tconfpy-X.XXX.tar.gz   (where X.XXX is the version number)
.fi

Win32 users who do not have tar installed on their system can find
a Windows version of the program at:

.nf
    http://unxutils.sourceforge.net/
.fi


.SS Install Method #1 - All Systems (Semi-Automated)


Enter the directory created in the unpacking step above.  Then issue
the following command:

.nf
    python setup.py install
.fi

This will install the \*(TC module and compile it.

You will manually have to copy the 'test-tc.py' program to a directory
somewhere in your executable path.  Similarly, copy the documentation
files to locations appropriate for your system.


.SS Install Method #2 - All Systems (Manual)


Enter the directory created in the unpacking step above.  Then,
manually copy the tconfpy.py file to a directory somewhere in your
PYTHONPATH.  The recommended location for Unix-like systems is:

.nf
    .../pythonX.Y/site-packages
.fi

For Win32 systems, the recommended location is:

.nf
    ...\\PythonX.Y\\lib\\site-packages
.fi

Where X.Y is the Python release number.


You can pre-compile the \*(TC module by starting Python interactively
and then issuing the command:

.nf
    import tconfpy
.fi

Manually copy the 'test-tc.py' program to a directory
somewhere in your executable path.  Copy the documentation
files to locations appropriate for your system.


.SS Install Method #3 - FreeBSD Only (Fully-Automated)


Make sure you are logged in as root, then:

.nf
    cd /usr/ports/devel/py-tconfpy
    make install
.fi

This is a fully-automated install that puts both code and
documentation where it belongs.  After this command has completed
you'll find the license agreement and all the documentation (in the
various formats) in:

.nf
    /usr/local/share/doc/py-tconfpy
.fi

The 'man' pages will have been properly installed so either of these
commands will work:

.nf
    man tconfpy
    man test-tc
.fi

.SS Bundling \*(TC With Your Own Programs


If you write a program that depends on \*(TC you'll need to ensure
that the end-users have it installed on their systems.  There are two
ways to do this:

1) Tell them to download and install the package as described above.
   This is not recommended since you cannot rely on the technical
   ability of end users to do this correctly.

2) Just include 'tconfpy.py' in your program distribution directory.
   This ensures that the module is available to your program
   regardless of what the end-user system has installed.




.SH OTHER

\*(TC requires Python 2.3 or later.

.SH BUGS AND MISFEATURES
None known as of this release.

.SH COPYRIGHT AND LICENSING
\*(TC is Copyright(c) \*(CP TundraWare Inc.  For terms of use, see
the tconfpy-license.txt file in the program distribution.  If you
install \*(TC  on a FreeBSD system using the 'ports' mechanism, you
will also find this file in /usr/local/share/doc/py-tconfpy.

.SH AUTHOR
.nf
Tim Daneliuk
tconfpy@tundraware.com