snit(n) | Snit's Not Incr Tcl, OO system | snit(n) |
snit - Snit's Not Incr Tcl
package require Tcl 8.5
package require snit ?2.3.2?
snit::type name definition
typevariable name ?-array? ?value?
typemethod name arglist body
typeconstructor body
variable name ?-array? ?value?
method name arglist body
option namespec ?defaultValue?
option namespec ?options...?
constructor arglist body
destructor body
proc name args body
delegate method name to comp ?as target?
delegate method name ?to comp? using pattern
delegate method * ?to comp? ?using pattern? ?except exceptions?
delegate option namespec to comp
delegate option namespec to comp as target
delegate option * to comp
delegate option * to comp except exceptions
component comp ?-public method? ?-inherit flag?
delegate typemethod name to comp ?as target?
delegate typemethod name ?to comp? using pattern
delegate typemethod * ?to comp? ?using pattern? ?except exceptions?
typecomponent comp ?-public typemethod? ?-inherit flag?
pragma ?options...?
expose comp
expose comp as method
onconfigure name arglist body
oncget name body
snit::widget name definition
widgetclass name
hulltype type
snit::widgetadaptor name definition
snit::typemethod type name arglist body
snit::method type name arglist body
snit::macro name arglist body
snit::compile which type body
$type typemethod args...
$type create name ?option value ...?
$type info typevars ?pattern?
$type info typemethods ?pattern?
$type info args method
$type info body method
$type info default method aname varname
$type info instances ?pattern?
$type destroy
$object method args...
$object configure ?option? ?value? ...
$object configurelist optionlist
$object cget option
$object destroy
$object info type
$object info vars ?pattern?
$object info typevars ?pattern?
$object info typemethods ?pattern?
$object info options ?pattern?
$object info methods ?pattern?
$object info args method
$object info body method
$object info default method aname varname
mymethod name ?args...?
mytypemethod name ?args...?
myproc name ?args...?
myvar name
mytypevar name
from argvName option ?defvalue?
install compName using objType objName args...
installhull using widgetType args...
installhull name
variable name
typevariable name
varname name
typevarname name
codename name
snit::boolean validate ?value?
snit::boolean name
snit::double validate ?value?
snit::double name ?option value...?
snit::enum validate ?value?
snit::enum name ?option value...?
snit::fpixels validate ?value?
snit::fpixels name ?option value...?
snit::integer validate ?value?
snit::integer name ?option value...?
snit::listtype validate ?value?
snit::listtype name ?option value...?
snit::pixels validate ?value?
snit::pixels name ?option value...?
snit::stringtype validate ?value?
snit::stringtype name ?option value...?
snit::window validate ?value?
snit::window name
Snit is a pure Tcl object and megawidget system. It's unique among Tcl object systems in that it's based not on inheritance but on delegation. Object systems based on inheritance only allow you to inherit from classes defined using the same system, which is limiting. In Tcl, an object is anything that acts like an object; it shouldn't matter how the object was implemented. Snit is intended to help you build applications out of the materials at hand; thus, Snit is designed to be able to incorporate and build on any object, whether it's a hand-coded object, a Tk widget, an Incr Tcl object, a BWidget or almost anything else.
This man page is intended to be a reference only; see the accompanying snitfaq for a gentler, more tutorial introduction to Snit concepts.
This man page covers both Snit 2.2 and Snit 1.3. The primary difference between the two versions is simply that Snit 2.2 contains speed optimizations based on new features of Tcl 8.5; Snit 1.3 supports all of Tcl 8.3, 8.4 and Tcl 8.5. There are a few minor inconsistencies; they are flagged in the body of the man page with the label "Snit 1.x Incompatibility"; they are also discussed in the snitfaq.
Snit provides the following commands for defining new types:
The type name is then a command that is used to create objects of the new type, along with other activities.
The snit::type definition block is a script that may contain the following definitions:
The variable type is automatically defined in the body to the type's fully-qualified name. In addition, type variables are automatically visible in the body of every type method.
If the name consists of two or more tokens, Snit handles it specially:
This statement implicitly defines a type method called a which has a subcommand b. b is called like this:
typemethod {a b} {arg} { puts "Got $arg" }
a may have any number of subcommands. This makes it possible to define a hierarchical command structure; see method, below, for more examples.
$type a b "Hello, world!"
Type methods can call commands from the namespace in which the type is defined without importing them, e.g., if the type name is ::parentns::typename, then the type's type methods can call ::parentns::someproc just as someproc. Snit 1.x Incompatibility: This does not work in Snit 1.x, as it depends on namespace path, a new command in Tcl 8.5.
Snit 1.x Incompatibility: In Snit 1.x, the following following two calls to this type method are equivalent:
In Snit 2.2, the second form is invalid.
$type a b "Hello, world!"
$type {a b} "Hello, world!"
The variable type is automatically defined in the body, and contains the type's fully-qualified name. In addition, type variables are automatically visible in the body of the type constructor.
A type may define at most one type constructor.
The type constructor can call commands from the namespace in which the type is defined without importing them, e.g., if the type name is ::parentns::typename, then the type constructor can call ::parentns::someproc just as someproc. Snit 1.x Incompatibility: This does not work in Snit 1.x, as it depends on namespace path, a new command in Tcl 8.5.
The method is implicitly passed the following arguments as well: type, which contains the fully-qualified type name; self, which contains the current instance command name; selfns, which contains the name of the instance's private namespace; and win, which contains the original instance name. Consequently, the arglist may not contain the argument names type, self, selfns, or win.
An instance method defined in this way is said to be locally defined.
Type and instance variables are automatically visible in all instance methods. If the type has locally defined options, the options array is also visible.
If the name consists of two or more tokens, Snit handles it specially:
This statement implicitly defines a method called a which has a subcommand b. b is called like this:
method {a b} {} { ... }
a may have any number of subcommands. This makes it possible to define a hierarchical command structure:
$self a b "Hello, world!"
% snit::type dog {What we've done is implicitly defined a "tail" method with subcommands "wag" and "droop". Consequently, it's an error to define "tail" explicitly.
method {tail wag} {} {return "Wag, wag"}
method {tail droop} {} {return "Droop, droop"} } ::dog % dog spot ::spot % spot tail wag Wag, wag % spot tail droop Droop, droop %
Methods can call commands from the namespace in which the type is defined without importing them, e.g., if the type name is ::parentns::typename, then the type's methods can call ::parentns::someproc just as someproc. Snit 1.x Incompatibility: This does not work in Snit 1.x, as it depends on namespace path, a new command in Tcl 8.5.
Snit 1.x Incompatibility: In Snit 1.x, the following following two calls to this method are equivalent:
In Snit 2.2, the second form is invalid.
$self a b "Hello, world!"
$self {a b} "Hello, world!"
An option defined in this way is said to be locally defined.
The namespec is a list defining the option's name, resource name, and class name, e.g.:
The option name must begin with a hyphen, and must not contain any upper case letters. The resource name and class name are optional; if not specified, the resource name defaults to the option name, minus the hyphen, and the class name defaults to the resource name with the first letter capitalized. Thus, the following statement is equivalent to the previous example:
option {-font font Font} {Courier 12}
See The Tk Option Database for more information about resource and class names.
option -font {Courier 12}
Options are normally set and retrieved using the standard instance methods configure and cget; within instance code (method bodies, etc.), option values are available through the options array:
If the type defines any option handlers (e.g., -configuremethod), then it should probably use configure and cget to access its options to avoid subtle errors.
set myfont $options(-font)
The option statement may include the following options:
For example, an option may declare that its value must be an integer by specifying snit::integer as its validation type:
It may also declare that its value is an integer between 1 and 10 by specifying a validation subtype:
option -number -type snit::integer
If a validation type or subtype is defined for an option, then it will be used to validate the option's value whenever it is changed by the object's configure or configurelist methods. In addition, all such options will have their values validated automatically immediately after the constructor executes.
option -number -type {snit::integer -min 1 -max 10}
Snit defines a family of validation types and subtypes, and it's quite simple to define new ones. See Validation Types for the complete list, and Defining Validation Types for an explanation of how to define your own.
The named method must take one argument, the option name. For example, this code is equivalent to (though slower than) Snit's default handling of cget:
Note that it's possible for any number of options to share a -cgetmethod.
option -font -cgetmethod GetOption
method GetOption {option} {
return $options($option)
}
The named method must take two arguments, the option name and its new value. For example, this code is equivalent to (though slower than) Snit's default handling of configure:
Note that it's possible for any number of options to share a single -configuremethod.
option -font -configuremethod SetOption
method SetOption {option value} {
set options($option) $value
}
The named method must take two arguments, the option name and its new value. For example, this code verifies that -flag's value is a valid Boolean value:
Note that it's possible for any number of options to share a single -validatemethod.
option -font -validatemethod CheckBoolean
method CheckBoolean {option value} {
if {![string is boolean -strict $value]} {
error "option $option must have a boolean value."
}
}
As with methods, the arguments type, self, selfns, and win are defined implicitly, and all type and instance variables are automatically visible in its body.
If the definition doesn't explicitly define the constructor, Snit defines one implicitly. If the type declares at least one option (whether locally or by delegation), the default constructor will be defined as follows:
For standard Tk widget behavior, the argument list should be the single name args, as shown.
constructor {args} {
$self configurelist $args
}
If the definition defines neither a constructor nor any options, the default constructor is defined as follows:
As with methods, the constructor can call commands from the namespace in which the type is defined without importing them, e.g., if the type name is ::parentns::typename, then the constructor can call ::parentns::someproc just as someproc. Snit 1.x Incompatibility: This does not work in Snit 1.x, as it depends on namespace path, a new command in Tcl 8.5.
constructor {} {}
The destructor takes no explicit arguments; as with methods, the arguments type, self, selfns, and win, are defined implicitly, and all type and instance variables are automatically visible in its body. As with methods, the destructor can call commands from the namespace in which the type is defined without importing them, e.g., if the type name is ::parentns::typename, then the destructor can call ::parentns::someproc just as someproc. Snit 1.x Incompatibility: This does not work in Snit 1.x, as it depends on namespace path, a new command in Tcl 8.5.
The defined proc differs from a normal Tcl proc in that all type variables are automatically visible. The proc can access instance variables as well, provided that it is passed selfns (with precisely that name) as one of its arguments.
Although they are not implicitly defined for procs, the argument names type, self, and win should be avoided.
As with methods and typemethods, procs can call commands from the namespace in which the type is defined without importing them, e.g., if the type name is ::parentns::typename, then the proc can call ::parentns::someproc just as someproc. Snit 1.x Incompatibility: This does not work in Snit 1.x, as it depends on namespace path, a new command in Tcl 8.5.
is roughly equivalent to this explicitly defined method:
delegate method wag to tail
As with methods, the name may have multiple tokens; in this case, the last token of the name is assumed to be the name of the component's method.
method wag {args} {
uplevel $tail wag $args
}
The optional as clause allows you to specify the delegated method name and possibly add some arguments:
delegate method wagtail to tail as "wag briskly"
A method cannot be both locally defined and delegated.
Note: All forms of delegate method can delegate to both instance components and type components.
The value of the using clause is a list that may contain any or all of the following substitution codes; these codes are substituted with the described value to build the delegated command prefix. Note that the following two statements are equivalent:
Each element of the list becomes a single element of the delegated command--it is never reparsed as a string.
delegate method wag to tail
delegate method wag to tail using "%c %m"
Substitutions:
In fact, the "*" can be a list of two or more tokens whose last element is "*", as in the following example:
This implicitly defines the method tail whose subcommands will be delegated to the tail component.
delegate method {tail *} to tail
Note that delegated options never appear in the options array.
method ConfigureMethod {option value} {
$comp configure $option $value
}
method CgetMethod {option} {
return [$comp cget $option]
}
If the as clause is specified, then the target option name is used in place of name.
The form delegate option * delegates all unknown options to the specified component. The except clause can be used to specify a list of exceptions, i.e., option names that will not be so delegated.
Warning: options can only be delegated to a component if it supports the configure and cget instance methods.
An option cannot be both locally defined and delegated. TBD: Continue from here.
If the -public option is specified, then the option is made public by defining a method whose subcommands are delegated to the component e.g., specifying -public mycomp is equivalent to the following:
If the -inherit option is specified, then flag must be a Boolean value; if flag is true then all unknown methods and options will be delegated to this component. The name -inherit implies that instances of this new type inherit, in a sense, the methods and options of the component. That is, -inherit yes is equivalent to:
component mycomp
delegate method {mymethod *} to mycomp
component mycomp
delegate option * to mycomp
delegate method * to mycomp
is roughly equivalent to this explicitly defined method:
delegate typemethod lostdogs to pound
As with type methods, the name may have multiple tokens; in this case, the last token of the name is assumed to be the name of the component's method.
typemethod lostdogs {args} {
uplevel $pound lostdogs $args
}
The optional as clause allows you to specify the delegated method name and possibly add some arguments:
delegate typemethod lostdogs to pound as "get lostdogs"
A type method cannot be both locally defined and delegated.
The value of the using clause is a list that may contain any or all of the following substitution codes; these codes are substituted with the described value to build the delegated command prefix. Note that the following two statements are equivalent:
Each element of the list becomes a single element of the delegated command--it is never reparsed as a string.
delegate typemethod lostdogs to pound
delegate typemethod lostdogs to pound using "%c %m"
Substitutions:
Note: By default, Snit interprets $type foo, where foo is not a defined type method, as equivalent to $type create foo, where foo is the name of a new instance of the type. If you use delegate typemethod *, then the create type method must always be used explicitly.
The "*" can be a list of two or more tokens whose last element is "*", as in the following example:
This implicitly defines the type method tail whose subcommands will be delegated to the tail type component.
delegate typemethod {tail *} to tail
If the -public option is specified, then the type component is made public by defining a typemethod whose subcommands are delegated to the type component, e.g., specifying -public mytypemethod is equivalent to the following:
If the -inherit option is specified, then flag must be a Boolean value; if flag is true then all unknown type methods will be delegated to this type component. (See the note on "delegate typemethod *", above.) The name -inherit implies that this type inherits, in a sense, the behavior of the type component. That is, -inherit yes is equivalent to:
typecomponent mycomp
delegate typemethod {mytypemethod *} to mycomp
typecomponent mycomp
delegate typemethod * to mycomp
By setting the -hastypeinfo, -hastypedestroy, and -hasinstances pragmas to false and defining appropriate type methods, you can create an ensemble command without any extraneous behavior.
This pragma and -hasinstances cannot both be set false.
This pragma and -hastypemethods cannot both be set false.
If false (the default), instance methods are dispatched normally. If true, a faster dispatching scheme is used instead. The speed comes at a price; with -simpledispatch yes you get the following limitations:
As of version 0.95, the following definitions,
are implemented as follows:
option -myoption
onconfigure -myoption {value} {
# Code to save the option's value
}
option -myoption -configuremethod _configure-myoption
method _configure-myoption {_option value} {
# Code to save the option's value
}
As of version 0.95, the following definitions,
are implemented as follows:
option -myoption
oncget -myoption {
# Code to return the option's value
}
option -myoption -cgetmethod _cget-myoption
method _cget-myoption {_option} {
# Code to return the option's value
}
The hull component is initially created with the requested widget name; then Snit does some magic, renaming the hull component and installing its own instance command in its place. The hull component's new name is saved in an instance variable called hull.
Note that in general it is not possible to change the widget class of a snit::widgetadaptor's hull widget.
See The Tk Option Database for information on how snit::widgetadaptors interact with the option database.
A macro is simply a Tcl proc that is defined in the slave interpreter used to compile type and widget definitions. Thus, macros have access to all of the type and widget definition statements. See Macros and Meta-programming for more details.
The macro name cannot be the same as any standard Tcl command, or any Snit type or widget definition statement, e.g., you can't redefine the method or delegate statements, or the standard set, list, or string commands.
This command exposes the "compiler". Given a definition body for the named type, where which is type, widget, or widgetadaptor, snit::compile returns a list of two elements. The first element is the fully qualified type name; the second element is the definition script.
snit::compile is useful when additional processing must be done on the Snit-generated code--if it must be instrumented, for example, or run through the TclDevKit compiler. In addition, the returned script could be saved in a ".tcl" file and used to define the type as part of an application or library, thus saving the compilation overhead at application start-up. Note that the same version of Snit must be used at run-time as at compile-time.
A type or widget definition creates a type command, which is used to create instances of the type. The type command has this form:
The type command is most often used to create new instances of the type; hence, the create method is assumed if the first argument to the type command doesn't name a valid type method, unless the type definition includes delegate typemethod * or the -hasinstances pragma is set to false.
Furthermore, if the -hastypemethods pragma is false, then Snit type commands can be called with no arguments at all; in this case, the type command creates an instance with an automatically generated name. In other words, provided that the -hastypemethods pragma is false and the type has instances, the following commands are equivalent:
snit::type dog { ... } set mydog [dog create %AUTO%] set mydog [dog %AUTO%] set mydog [dog]This doesn't work for Snit widgets, for obvious reasons.
Snit 1.x Incompatibility: In Snit 1.x, the above behavior is available whether -hastypemethods is true (the default) or false.
In addition to any type methods in the type's definition, all type and widget commands will usually have at least the following subcommands:
For snit::types, if name is not a fully-qualified command name, it is assumed to be a name in the namespace in which the call to snit::type appears. The method returns the fully-qualified instance name.
For snit::widgets and snit::widgetadaptors, name must be a valid widget name; the method returns the widget name.
So long as name does not conflict with any defined type method name the create keyword may be omitted, unless the type definition includes delegate typemethod * or the -hasinstances pragma is set to false.
If the name includes the string %AUTO%, it will be replaced with the string $type$counter where $type is the type name and $counter is a counter that increments each time %AUTO% is used for this type.
By default, any arguments following the name will be a list of option names and their values; however, a type's constructor can specify a different argument list.
As of Snit V0.95, create will throw an error if the name is the same as any existing command--note that this was always true for snit::widgets and snit::widgetadaptors. You can restore the previous behavior using the -canreplace pragma.
If pattern is given, it's used as a string match pattern; only names that match the pattern are returned.
If the type definition includes delegate typemethod *, the list will include only the names of those implicitly delegated type methods that have been called at least once and are still in the type method cache.
If pattern is given, it's used as a string match pattern; only names that match the pattern are returned.
If pattern is given, it's used as a string match pattern; only names that match the pattern are returned.
Snit 1.x Incompatibility: In Snit 1.x, the full multi-word names of hierarchical type methods are included in the return value.
A Snit type or widget's create type method creates objects of the type; each object has a unique name that is also a Tcl command. This command is used to access the object's methods and data, and has this form:
In addition to any delegated or locally-defined instance methods in the type's definition, all Snit objects will have at least the following subcommands:
Warning: This information will be available for delegated options only if the component to which they are delegated has a configure method that returns this same kind of information.
Note: Snit defines this method only if the type has at least one option.
Note: Snit defines this method only if the type has at least one option.
Note: Snit defines this method only if the type has at least one option.
Note: The destroy method isn't defined for snit::widget or snit::widgetadaptor objects; instances of these are destroyed by calling Tk's destroy command, just as normal widgets are.
If pattern is given, it's used as a string match pattern; only names that match the pattern are returned.
If pattern is given, it's used as a string match pattern; only names that match the pattern are returned.
If the type definition includes delegate typemethod *, the list will include only the names of those implicitly delegated type methods that have been called at least once and are still in the type method cache.
If pattern is given, it's used as a string match pattern; only names that match the pattern are returned.
Snit 1.x Incompatibility: In Snit 1.x, the full multi-word names of hierarchical type methods are included in the return value.
If pattern is given, it's used as a string match pattern; only names that match the pattern are returned.
Note that the return value might be different for different instances of the same type, if component object types can vary from one instance to another.
If the type definition includes delegate method *, the list will include only the names of those implicitly delegated methods that have been called at least once and are still in the method cache.
If pattern is given, it's used as a string match pattern; only names that match the pattern are returned.
Snit 1.x Incompatibility: In Snit 1.x, the full multi-word names of hierarchical type methods are included in the return value.
Snit defines the following commands for use in your object code: that is, for use in type methods, instance methods, constructors, destructors, onconfigure handlers, oncget handlers, and procs. They do not reside in the ::snit:: namespace; instead, they are created with the type, and can be used without qualification.
The chief distinction between the two is that the latter form will not break if the object's command is renamed.
$button configure -command [list $self dosomething myargument]
$button configure -command [mymethod dosomething myargument]
Type commands cannot be renamed, so in practice there's little difference between the two forms. mytypemethod is provided for parallelism with mymethod.
$button configure -command [list $type dosomething myargument]
$button configure -command [mytypemethod dosomething myargument]
$button configure -command [list ${type}::dosomething myargument]
$button configure -command [myproc dosomething myargument]
from looks for option in the option list. If it is found, it and its value are removed from the list, and the value is returned. If option doesn't appear in the list, then the defvalue is returned. If the option is locally-defined option, and defvalue is not specified, then the option's default value as specified in the type definition will be returned instead.
Note that whichever method is used, compName must still be declared in the type definition using component, or must be referenced in at least one delegate statement.
install myComp using myObjType $self.myComp args...
set myComp [myObjType $self.myComp args...]
If this is a snit::widget or snit::widgetadaptor, and if options have been delegated to component compName, then those options will receive default values from the Tk option database. Note that it doesn't matter whether the component to be installed is a widget or not. See The Tk Option Database for more information.
install cannot be used to install type components; just assign the type component's command name to the type component's variable instead.
The first form specifies the widgetType and the args... (that is, the hardcoded option list) to use in creating the hull. Given this form, installhull creates the hull widget, and initializes any options delegated to the hull from the Tk option database.
In the second form, the hull widget has already been created; note that its name must be "$win". In this case, the Tk option database is not queried for any options delegated to the hull. The longer form is preferred; however, the shorter form allows the programmer to adapt a widget created elsewhere, which is sometimes useful. For example, it can be used to adapt a "page" widget created by a BWidgets tabbed notebook or pages manager widget.
See The Tk Option Database for more information about snit::widgetadaptors and the option database.
It's generally clearest to define all instance variables in the type definition, and omit declaring them in methods and so forth.
Note that this is an instance-specific version of the standard Tcl ::variable command.
It's generally clearest to declare all type variables in the type definition, and omit declaring them in methods, type methods, etc.
Given an instance variable name, returns the fully qualified name. Use this if you're passing the variable to some other object, e.g., as a -textvariable to a Tk label widget.
Given a type variable name, returns the fully qualified name. Use this if you're passing the type variable to some other object, e.g., as a -textvariable to a Tk label widget.
When an object includes other objects, as when a toolbar contains buttons or a GUI object contains an object that references a database, the included object is called a component. The standard way to handle component objects owned by a Snit object is to declare them using component, which creates a component instance variable. In the following example, a dog object has a tail object:
snit::type dog {
component mytail
constructor {args} {
set mytail [tail %AUTO% -partof $self]
$self configurelist $args
}
method wag {} {
$mytail wag
}
}
snit::type tail {
option -length 5
option -partof
method wag {} { return "Wag, wag, wag."}
}
Because the tail object's name is stored in an instance variable, it's easily accessible in any method.
The install command provides an alternate way to create and install the component:
snit::type dog {
component mytail
constructor {args} {
install mytail using tail %AUTO% -partof $self
$self configurelist $args
}
method wag {} {
$mytail wag
}
}
For snit::types, the two methods are equivalent; for snit::widgets and snit::widgetadaptors, the install command properly initializes the widget's options by querying The Tk Option Database.
In the above examples, the dog object's wag method simply calls the tail component's wag method. In OO jargon, this is called delegation. Snit provides an easier way to do this:
snit::type dog {
delegate method wag to mytail
constructor {args} {
install mytail using tail %AUTO% -partof $self
$self configurelist $args
}
}
The delegate statement in the type definition implicitly defines the instance variable mytail to hold the component's name (though it's good form to use component to declare it explicitly); it also defines the dog object's wag method, delegating it to the mytail component.
If desired, all otherwise unknown methods can be delegated to a specific component:
snit::type dog { delegate method * to mytail constructor {args} { set mytail [tail %AUTO% -partof $self] $self configurelist $args } method bark { return "Bark, bark, bark!" }
}
In this case, a dog object will handle its own bark method; but wag will be passed along to mytail. Any other method, being recognized by neither dog nor tail, will simply raise an error.
Option delegation is similar to method delegation, except for the interactions with the Tk option database; this is described in The Tk Option Database.
The relationship between type components and instance components is identical to that between type variables and instance variables, and that between type methods and instance methods. Just as an instance component is an instance variable that holds the name of a command, so a type component is a type variable that holds the name of a command. In essence, a type component is a component that's shared by every instance of the type.
Just as delegate method can be used to delegate methods to instance components, as described in Components and Delegation, so delegate typemethod can be used to delegate type methods to type components.
Note also that as of Snit 0.95 delegate method can delegate methods to both instance components and type components.
This section describes how Snit interacts with the Tk option database, and assumes the reader has a working knowledge of the option database and its uses. The book Practical Programming in Tcl and Tk by Welch et al has a good introduction to the option database, as does Effective Tcl/Tk Programming.
Snit is implemented so that most of the time it will simply do the right thing with respect to the option database, provided that the widget developer does the right thing by Snit. The body of this section goes into great deal about what Snit requires. The following is a brief statement of the requirements, for reference.
The interaction of Tk widgets with the option database is a complex thing; the interaction of Snit with the option database is even more so, and repays attention to detail.
Setting the widget class: Every Tk widget has a widget class. For Tk widgets, the widget class name is the just the widget type name with an initial capital letter, e.g., the widget class for button widgets is "Button".
Similarly, the widget class of a snit::widget defaults to the unqualified type name with the first letter capitalized. For example, the widget class of
snit::widget ::mylibrary::scrolledText { ... }
is "ScrolledText". The widget class can also be set explicitly using the widgetclass statement within the snit::widget definition.
Any widget can be used as the hulltype provided that it supports the -class option for changing its widget class name. See the discussion of the hulltype command, above. The user may pass -class to the widget at instantion.
The widget class of a snit::widgetadaptor is just the widget class of its hull widget; this cannot be changed unless the hull widget supports -class, in which case it will usually make more sense to use snit::widget rather than snit::widgetadaptor.
Setting option resource names and classes: In Tk, every option has three names: the option name, the resource name, and the class name. The option name begins with a hyphen and is all lowercase; it's used when creating widgets, and with the configure and cget commands.
The resource and class names are used to initialize option default values by querying the Tk option database. The resource name is usually just the option name minus the hyphen, but may contain uppercase letters at word boundaries; the class name is usually just the resource name with an initial capital, but not always. For example, here are the option, resource, and class names for several text widget options:
-background background Background
-borderwidth borderWidth BorderWidth
-insertborderwidth insertBorderWidth BorderWidth
-padx padX Pad
As is easily seen, sometimes the resource and class names can be inferred from the option name, but not always.
Snit options also have a resource name and a class name. By default, these names follow the rule given above: the resource name is the option name without the hyphen, and the class name is the resource name with an initial capital. This is true for both locally-defined options and explicitly delegated options:
snit::widget mywidget {
option -background
delegate option -borderwidth to hull
delegate option * to text # ...
}
In this case, the widget class name is "Mywidget". The widget has the following options: -background, which is locally defined, and -borderwidth, which is explicitly delegated; all other widgets are delegated to a component called "text", which is probably a Tk text widget. If so, mywidget has all the same options as a text widget. The option, resource, and class names are as follows:
-background background Background
-borderwidth borderwidth Borderwidth
-padx padX Pad
Note that the locally defined option, -background, happens to have the same three names as the standard Tk -background option; and -pad, which is delegated implicitly to the text component, has the same three names for mywidget as it does for the text widget. -borderwidth, on the other hand, has different resource and class names than usual, because the internal word "width" isn't capitalized. For consistency, it should be; this is done as follows:
snit::widget mywidget { option -background delegate option {-borderwidth borderWidth} to hull delegate option * to text # ...
}
The class name will default to "BorderWidth", as expected.
Suppose, however, that mywidget also delegated -padx and -pady to the hull. In this case, both the resource name and the class name must be specified explicitly:
snit::widget mywidget { option -background delegate option {-borderwidth borderWidth} to hull delegate option {-padx padX Pad} to hull delegate option {-pady padY Pad} to hull delegate option * to text # ...
}
Querying the option database: If you set your widgetclass and option names as described above, Snit will query the option database when each instance is created, and will generally do the right thing when it comes to querying the option database. The remainder of this section goes into the gory details.
Initializing locally defined options: When an instance of a snit::widget is created, its locally defined options are initialized as follows: each option's resource and class names are used to query the Tk option database. If the result is non-empty, it is used as the option's default; otherwise, the default hardcoded in the type definition is used. In either case, the default can be overridden by the caller. For example,
option add *Mywidget.texture pebbled
snit::widget mywidget { option -texture smooth # ...
}
mywidget .mywidget -texture greasy
Here, -texture would normally default to "smooth", but because of the entry added to the option database it defaults to "pebbled". However, the caller has explicitly overridden the default, and so the new widget will be "greasy".
Initializing options delegated to the hull: A snit::widget's hull is a widget, and given that its class has been set it is expected to query the option database for itself. The only exception concerns options that are delegated to it with a different name. Consider the following code:
option add *Mywidget.borderWidth 5
option add *Mywidget.relief sunken
option add *Mywidget.hullbackground red
option add *Mywidget.background green
snit::widget mywidget { delegate option -borderwidth to hull delegate option -hullbackground to hull as -background delegate option * to hull # ...
}
mywidget .mywidget
set A [.mywidget cget -relief]
set B [.mywidget cget -hullbackground]
set C [.mywidget cget -background]
set D [.mywidget cget -borderwidth]
The question is, what are the values of variables A, B, C and D?
The value of A is "sunken". The hull is a Tk frame that has been given the widget class "Mywidget"; it will automatically query the option database and pick up this value. Since the -relief option is implicitly delegated to the hull, Snit takes no action.
The value of B is "red". The hull will automatically pick up the value "green" for its -background option, just as it picked up the -relief value. However, Snit knows that -hullbackground is mapped to the hull's -background option; hence, it queries the option database for -hullbackground and gets "red" and updates the hull accordingly.
The value of C is also "red", because -background is implicitly delegated to the hull; thus, retrieving it is the same as retrieving -hullbackground. Note that this case is unusual; in practice, -background would probably be explicitly delegated to some other component.
The value of D is "5", but not for the reason you think. Note that as it is defined above, the resource name for -borderwidth defaults to "borderwidth", whereas the option database entry is "borderWidth". As with -relief, the hull picks up its own -borderwidth option before Snit does anything. Because the option is delegated under its own name, Snit assumes that the correct thing has happened, and doesn't worry about it any further.
For snit::widgetadaptors, the case is somewhat altered. Widget adaptors retain the widget class of their hull, and the hull is not created automatically by Snit. Instead, the snit::widgetadaptor must call installhull in its constructor. The normal way to do this is as follows:
snit::widgetadaptor mywidget { # ... constructor {args} { # ... installhull using text -foreground white # } #...
}
In this case, the installhull command will create the hull using a command like this:
set hull [text $win -foreground white]
The hull is a text widget, so its widget class is "Text". Just as with snit::widget hulls, Snit assumes that it will pick up all of its normal option values automatically; options delegated from a different name are initialized from the option database in the same way.
Initializing options delegated to other components: Non-hull components are matched against the option database in two ways. First, a component widget remains a widget still, and therefore is initialized from the option database in the usual way. Second, the option database is queried for all options delegated to the component, and the component is initialized accordingly--provided that the install command is used to create it.
Before option database support was added to Snit, the usual way to create a component was to simply create it in the constructor and assign its command name to the component variable:
snit::widget mywidget { delegate option -background to myComp constructor {args} { set myComp [text $win.text -foreground black] }
}
The drawback of this method is that Snit has no opportunity to initialize the component properly. Hence, the following approach is now used:
snit::widget mywidget { delegate option -background to myComp constructor {args} { install myComp using text $win.text -foreground black }
}
The install command does the following:
Non-widget components: The option database is never queried for snit::types, since it can only be queried given a Tk widget name. However, snit::widgets can have non-widget components. And if options are delegated to those components, and if the install command is used to install those components, then they will be initialized from the option database just as widget components are.
The snit::macro command enables a certain amount of meta-programming with Snit classes. For example, suppose you like to define properties: instance variables that have set/get methods. Your code might look like this:
snit::type dog {
variable mood happy
method getmood {} {
return $mood
}
method setmood {newmood} {
set mood $newmood
}
}
That's nine lines of text per property. Or, you could define the following snit::macro:
snit::macro property {name initValue} {
variable $name $initValue
method get$name {} "return $name"
method set$name {value} "set $name \$value"
}
Note that a snit::macro is just a normal Tcl proc defined in the slave interpreter used to compile type and widget definitions; as a result, it has access to all the commands used to define types and widgets.
Given this new macro, you can define a property in one line of code:
Within a macro, the commands variable and proc refer to the Snit type-definition commands, not the standard Tcl commands. To get the standard Tcl commands, use _variable and _proc.
snit::type dog {
property mood happy
}
Because a single slave interpreter is used for compiling all Snit types and widgets in the application, there's the possibility of macro name collisions. If you're writing a reuseable package using Snit, and you use some snit::macros, define them in your package namespace:
This leaves the global namespace open for application authors.
snit::macro mypkg::property {name initValue} { ... }
snit::type dog {
mypkg::property mood happy
}
A validation type is an object that can be used to validate Tcl values of a particular kind. For example, snit::integer is used to validate that a Tcl value is an integer.
Every validation type has a validate method which is used to do the validation. This method must take a single argument, the value to be validated; further, it must do nothing if the value is valid, but throw an error if the value is invalid:
snit::integer validate 5 ;# Does nothing
snit::integer validate 5.0 ;# Throws an error (not an integer!)
The validate method will always return the validated value on success, and throw the -errorcode INVALID on error.
Snit defines a family of validation types, all of which are implemented as snit::type's. They can be used as is; in addition, their instances serve as parameterized subtypes. For example, a probability is a number between 0.0 and 1.0 inclusive:
The example above creates an instance of snit::double--a validation subtype--called probability, which can be used to validate probability values:
snit::double probability -min 0.0 -max 1.0
Validation subtypes can be defined explicitly, as in the above example; when a locally-defined option's -type is specified, they may also be created on the fly:
probability validate 0.5 ;# Does nothing
probability validate 7.9 ;# Throws an error
snit::enum ::dog::breed -values {mutt retriever sheepdog}
snit::type dog {
# Define subtypes on the fly...
option -breed -type {
snit::enum -values {mutt retriever sheepdog}
}
# Or use predefined subtypes...
option -breed -type ::dog::breed
}
Any object that has a validate method with the semantics described above can be used as a validation type; see Defining Validation Types for information on how to define new ones.
Snit defines the following validation types:
Note that this option doesn't support defining new validation subtypes on the fly; that is, the following code will not work (yet, anyway):
option -numbers -type {snit::listtype -type snit::integer}
Instead, define the subtype explicitly:
option -numbers -type {
snit::listtype -type {snit::integer -min 5}
}
snit::integer gt4 -min 5
snit::type mytype {
option -numbers -type {snit::listtype -type gt4}
}
There are three ways to define a new validation type: as a subtype of one of Snit's validation types, as a validation type command, and as a full-fledged validation type similar to those provided by Snit. Defining subtypes of Snit's validation types is described above, under Validation Types.
The next simplest way to create a new validation type is as a validation type command. A validation type is simply an object that has a validate method; the validate method must take one argument, a value, return the value if it is valid, and throw an error with -errorcode INVALID if the value is invalid. This can be done with a simple proc. For example, the snit::boolean validate type could have been implemented like this:
A validation type defined in this way cannot be subtyped, of course; but for many applications this will be sufficient.
proc ::snit::boolean {"validate" value} {
if {![string is boolean -strict $value]} {
return -code error -errorcode INVALID \
"invalid boolean \"$value\", should be one of: 1, 0, ..."
}
return $value
}
Finally, one can define a full-fledged, subtype-able validation type as a snit::type. Here's a skeleton to get you started:
And now you have a type that can be subtyped.
snit::type myinteger {
# First, define any options you'd like to use to define
# subtypes. Give them defaults such that they won't take
# effect if they aren't used, and marked them "read-only".
# After all, you shouldn't be changing their values after
# a subtype is defined.
#
# For example:
option -min -default "" -readonly 1
option -max -default "" -readonly 1
# Next, define a "validate" type method which should do the
# validation in the basic case. This will allow the
# type command to be used as a validation type.
typemethod validate {value} {
if {![string is integer -strict $value]} {
return -code error -errorcode INVALID \
"invalid value \"$value\", expected integer"
}
return $value
}
# Next, the constructor should validate the subtype options,
# if any. Since they are all readonly, we don't need to worry
# about validating the options on change.
constructor {args} {
# FIRST, get the options
$self configurelist $args
# NEXT, validate them.
# I'll leave this to your imagination.
}
# Next, define a "validate" instance method; its job is to
# validate values for subtypes.
method validate {value} {
# First, call the type method to do the basic validation.
$type validate $value
# Now we know it's a valid integer.
if {("" != $options(-min) && $value < $options(-min)) ||
("" != $options(-max) && $value > $options(-max))} {
# It's out of range; format a detailed message about
# the error, and throw it.
set msg "...."
return -code error -errorcode INVALID $msg
}
# Otherwise, if it's valid just return it.
return $valid
}
}
The file "validate.tcl" in the Snit distribution defines all of Snit's validation types; you can find the complete implementation for snit::integer and the other types there, to use as examples for your own types.
If you have problems, find bugs, or new ideas you are hereby cordially invited to submit a report of your problem, bug, or idea at the SourceForge trackers for tcllib, which can be found at http://sourceforge.net/projects/tcllib/. The relevant category is snit.
Additionally, you might wish to join the Snit mailing list; see http://www.wjduquette.com/snit for details.
One particular area to watch is using snit::widgetadaptor to adapt megawidgets created by other megawidget packages; correct widget destruction depends on the order of the <Destroy> bindings. The wisest course is simply not to do this.
During the course of developing Notebook (See http://www.wjduquette.com/notebook), my Tcl-based personal notebook application, I found I was writing it as a collection of objects. I wasn't using any particular object-oriented framework; I was just writing objects in pure Tcl following the guidelines in my Guide to Object Commands (see http://www.wjduquette.com/tcl/objects.html), along with a few other tricks I'd picked up since. And though it was working well, it quickly became tiresome because of the amount of boilerplate code associated with each new object type.
So that was one thing--tedium is a powerful motivator. But the other thing I noticed is that I wasn't using inheritance at all, and I wasn't missing it. Instead, I was using delegation: objects that created other objects and delegated methods to them.
And I said to myself, "This is getting tedious...there has got to be a better way." And one afternoon, on a whim, I started working on Snit, an object system that works the way Tcl works. Snit doesn't support inheritance, but it's great at delegation, and it makes creating megawidgets easy.
If you have any comments or suggestions (or bug reports!) don't hesitate to send me e-mail at will@wjduquette.com. In addition, there's a Snit mailing list; you can find out more about it at the Snit home page (see http://www.wjduquette.com/snit).
Snit has been designed and implemented from the very beginning by William H. Duquette. However, much credit belongs to the following people for using Snit and providing me with valuable feedback: Rolf Ade, Colin McCormack, Jose Nazario, Jeff Godfrey, Maurice Diamanti, Egon Pasztor, David S. Cargo, Tom Krehbiel, Michael Cleverly, Andreas Kupries, Marty Backe, Andy Goth, Jeff Hobbs, Brian Griffin, Donal Fellows, Miguel Sofer, Kenneth Green, and Anton Kovalenko. If I've forgotten anyone, my apologies; let me know and I'll add your name to the list.
This document, and the package it describes, will undoubtedly contain bugs and other problems. Please report such in the category snit of the Tcllib SF Trackers [http://sourceforge.net/tracker/?group_id=12883]. Please also report any ideas for enhancements you may have for either package and/or documentation.
BWidget, C++, Incr Tcl, Snit, adaptors, class, mega widget, object, object oriented, type, widget, widget adaptors
Programming tools
Copyright (c) 2003-2009, by William H. Duquette
2.3.2 | snit |