VariantType

This section introduces the GVariant type system. It is based, in large part, on the D-Bus type system, with two major changes and some minor lifting of restrictions. The D-Bus specification, therefore, provides a significant amount of information that is useful when working with GVariant.

The first major change with respect to the D-Bus type system is the introduction of maybe (or "nullable") types. Any type in GVariant can be converted to a maybe type, in which case, "nothing" (or "null") becomes a valid value. Maybe types have been added by introducing the character "m" to type strings.

The second major change is that the GVariant type system supports the concept of "indefinite types" -- types that are less specific than the normal types found in D-Bus. For example, it is possible to speak of "an array of any type" in GVariant, where the D-Bus type system would require you to speak of "an array of integers" or "an array of strings". Indefinite types have been added by introducing the characters "*", "?" and "r" to type strings.

Finally, all arbitrary restrictions relating to the complexity of types are lifted along with the restriction that dictionary entries may only appear nested inside of arrays.

Just as in D-Bus, GVariant types are described with strings ("type strings"). Subject to the differences mentioned above, these strings are of the same form as those found in DBus. Note, however: D-Bus always works in terms of messages and therefore individual type strings appear nowhere in its interface. Instead, "signatures" are a concatenation of the strings of the type of each argument in a message. GVariant deals with single values directly so GVariant type strings always describe the type of exactly one value. This means that a D-Bus signature string is generally not a valid GVariant type string -- except in the case that it is the signature of a message containing exactly one argument.

An indefinite type is similar in spirit to what may be called an abstract type in other type systems. No value can exist that has an indefinite type as its type, but values can exist that have types that are subtypes of indefinite types. That is to say, g_variant_get_type() will never return an indefinite type, but calling g_variant_is_of_type() with an indefinite type may return %TRUE. For example, you cannot have a value that represents "an array of no particular type", but you can have an "array of integers" which certainly matches the type of "an array of no particular type", since "array of integers" is a subtype of "array of no particular type".

This is similar to how instances of abstract classes may not directly exist in other type systems, but instances of their non-abstract subtypes may. For example, in GTK, no object that has the type of #GtkBin can exist (since #GtkBin is an abstract class), but a #GtkWindow can certainly be instantiated, and you would say that the #GtkWindow is a #GtkBin (since #GtkWindow is a subclass of #GtkBin).

GVariant Type Strings

A GVariant type string can be any of the following:

- any basic type string (listed below)

- "v", "r" or "*"

- one of the characters 'a' or 'm', followed by another type string

- the character '(', followed by a concatenation of zero or more other type strings, followed by the character ')'

- the character '{', followed by a basic type string (see below), followed by another type string, followed by the character '}'

A basic type string describes a basic type (as per g_variant_type_is_basic()) and is always a single character in length. The valid basic type strings are "b", "y", "n", "q", "i", "u", "x", "t", "h", "d", "s", "o", "g" and "?".

The above definition is recursive to arbitrary depth. "aaaaai" and "(ui(nq((y)))s)" are both valid type strings, as is "a(aa(ui)(qna{ya(yd)}))".

The meaning of each of the characters is as follows: - b: the type string of %G_VARIANT_TYPE_BOOLEAN; a boolean value. - y: the type string of %G_VARIANT_TYPE_BYTE; a byte. - n: the type string of %G_VARIANT_TYPE_INT16; a signed 16 bit integer. - q: the type string of %G_VARIANT_TYPE_UINT16; an unsigned 16 bit integer. - i: the type string of %G_VARIANT_TYPE_INT32; a signed 32 bit integer. - u: the type string of %G_VARIANT_TYPE_UINT32; an unsigned 32 bit integer. - x: the type string of %G_VARIANT_TYPE_INT64; a signed 64 bit integer. - t: the type string of %G_VARIANT_TYPE_UINT64; an unsigned 64 bit integer. - h: the type string of %G_VARIANT_TYPE_HANDLE; a signed 32 bit value that, by convention, is used as an index into an array of file descriptors that are sent alongside a D-Bus message. - d: the type string of %G_VARIANT_TYPE_DOUBLE; a double precision floating point value. - s: the type string of %G_VARIANT_TYPE_STRING; a string. - o: the type string of %G_VARIANT_TYPE_OBJECT_PATH; a string in the form of a D-Bus object path. - g: the type string of %G_VARIANT_TYPE_STRING; a string in the form of a D-Bus type signature. - ?: the type string of %G_VARIANT_TYPE_BASIC; an indefinite type that is a supertype of any of the basic types. - v: the type string of %G_VARIANT_TYPE_VARIANT; a container type that contain any other type of value. - a: used as a prefix on another type string to mean an array of that type; the type string "ai", for example, is the type of an array of signed 32-bit integers. - m: used as a prefix on another type string to mean a "maybe", or "nullable", version of that type; the type string "ms", for example, is the type of a value that maybe contains a string, or maybe contains nothing. - (): used to enclose zero or more other concatenated type strings to create a tuple type; the type string "(is)", for example, is the type of a pair of an integer and a string. - r: the type string of %G_VARIANT_TYPE_TUPLE; an indefinite type that is a supertype of any tuple type, regardless of the number of items. - {}: used to enclose a basic type string concatenated with another type string to create a dictionary entry type, which usually appears inside of an array to form a dictionary; the type string "a{sd}", for example, is the type of a dictionary that maps strings to double precision floating point values.

The first type (the basic type) is the key type and the second type is the value type. The reason that the first type is restricted to being a basic type is so that it can easily be hashed. - *: the type string of %G_VARIANT_TYPE_ANY; the indefinite type that is a supertype of all types. Note that, as with all type strings, this character represents exactly one type. It cannot be used inside of tuples to mean "any number of items".

Any type string of a container that contains an indefinite type is, itself, an indefinite type. For example, the type string "a*" (corresponding to %G_VARIANT_TYPE_ARRAY) is an indefinite type that is a supertype of every array type. "(*s)" is a supertype of all tuples that contain exactly two items where the second item is a string.

"a{?*}" is an indefinite type that is a supertype of all arrays containing dictionary entries where the key is any basic type and the value is any type at all. This is, by definition, a dictionary, so this type string corresponds to %G_VARIANT_TYPE_DICTIONARY. Note that, due to the restriction that the key of a dictionary entry must be a basic type, "{**}" is not a valid type string.

Constructors

this
this(GVariantType* gVariantType, bool ownedRef)

Sets our main struct and passes it to the parent class.

this
this(string typeString)

Creates a new #GVariantType corresponding to the type string given by @type_string. It is appropriate to call g_variant_type_free() on the return value.

this
this(VariantType element)

Constructs the type corresponding to an array of elements of the type @type.

this
this(VariantType key, VariantType value)

Constructs the type corresponding to a dictionary entry with a key of type @key and a value of type @value.

this
this(VariantType[] items)

Constructs a new tuple type, from @items.

Members

Functions

copy
VariantType copy()

Makes a copy of a #GVariantType. It is appropriate to call g_variant_type_free() on the return value. @type may not be %NULL.

dupString
string dupString()

Returns a newly-allocated copy of the type string corresponding to @type. The returned string is nul-terminated. It is appropriate to call g_free() on the return value.

element
VariantType element()

Determines the element type of an array or maybe type.

equal
bool equal(VariantType type2)

Compares @type1 and @type2 for equality.

first
VariantType first()

Determines the first item type of a tuple or dictionary entry type.

free
void free()

Frees a #GVariantType that was allocated with g_variant_type_copy(), g_variant_type_new() or one of the container type constructor functions.

getStringLength
size_t getStringLength()

Returns the length of the type string corresponding to the given @type. This function must be used to determine the valid extent of the memory region returned by g_variant_type_peek_string().

getStruct
void* getStruct()

the main Gtk struct as a void*

getVariantTypeStruct
GVariantType* getVariantTypeStruct()

Get the main Gtk struct

hash
uint hash()

Hashes @type.

isArray
bool isArray()

Determines if the given @type is an array type. This is true if the type string for @type starts with an 'a'.

isBasic
bool isBasic()

Determines if the given @type is a basic type.

isContainer
bool isContainer()

Determines if the given @type is a container type.

isDefinite
bool isDefinite()

Determines if the given @type is definite (ie: not indefinite).

isDictEntry
bool isDictEntry()

Determines if the given @type is a dictionary entry type. This is true if the type string for @type starts with a '{'.

isMaybe
bool isMaybe()

Determines if the given @type is a maybe type. This is true if the type string for @type starts with an 'm'.

isSubtypeOf
bool isSubtypeOf(VariantType supertype)

Checks if @type is a subtype of @supertype.

isTuple
bool isTuple()

Determines if the given @type is a tuple type. This is true if the type string for @type starts with a '(' or if @type is %G_VARIANT_TYPE_TUPLE.

isVariant
bool isVariant()

Determines if the given @type is the variant type.

key
VariantType key()

Determines the key type of a dictionary entry type.

nItems
size_t nItems()

Determines the number of items contained in a tuple or dictionary entry type.

next
VariantType next()

Determines the next item type of a tuple or dictionary entry type.

peekString
string peekString()

Returns the type string corresponding to the given @type. The result is not nul-terminated; in order to determine its length you must call g_variant_type_get_string_length().

value
VariantType value()

Determines the value type of a dictionary entry type.

Static functions

checked
VariantType checked(string arg0)
newMaybe
VariantType newMaybe(VariantType element)

Constructs the type corresponding to a maybe instance containing type type or Nothing.

stringIsValid
bool stringIsValid(string typeString)

Checks if @type_string is a valid GVariant type string. This call is equivalent to calling g_variant_type_string_scan() and confirming that the following character is a nul terminator.

stringScan
bool stringScan(string str, string limit, string endptr)

Scan for a single complete and valid GVariant type string in @string. The memory pointed to by @limit (or bytes beyond it) is never accessed.

Variables

gVariantType
GVariantType* gVariantType;

the main Gtk struct

ownedRef
bool ownedRef;
Undocumented in source.

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