Copyright | Will Thompson Iñaki García Etxebarria and Jonas Platte |
---|---|
License | LGPL-2.1 |
Maintainer | Iñaki García Etxebarria (inaki@blueleaf.cc) |
Safe Haskell | None |
Language | Haskell2010 |
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,
variantGetType
will never return an indefinite type, but
calling variantIsOfType
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
variantTypeIsBasic
) 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)}))". In order to not hit memory limits, GVariant
imposes a limit on recursion depth of 65 nested containers. This is the
limit in the D-Bus specification (64) plus one to allow a GDBusMessage
to
be nested in a top-level tuple.
The meaning of each of the characters is as follows:
b
: the type string ofG_VARIANT_TYPE_BOOLEAN
; a boolean value.y
: the type string ofG_VARIANT_TYPE_BYTE
; a byte.n
: the type string ofG_VARIANT_TYPE_INT16
; a signed 16 bit integer.q
: the type string ofG_VARIANT_TYPE_UINT16
; an unsigned 16 bit integer.i
: the type string ofG_VARIANT_TYPE_INT32
; a signed 32 bit integer.u
: the type string ofG_VARIANT_TYPE_UINT32
; an unsigned 32 bit integer.x
: the type string ofG_VARIANT_TYPE_INT64
; a signed 64 bit integer.t
: the type string ofG_VARIANT_TYPE_UINT64
; an unsigned 64 bit integer.h
: the type string ofG_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 ofG_VARIANT_TYPE_DOUBLE
; a double precision floating point value.s
: the type string ofG_VARIANT_TYPE_STRING
; a string.o
: the type string ofG_VARIANT_TYPE_OBJECT_PATH
; a string in the form of a D-Bus object path.g
: the type string ofG_VARIANT_TYPE_SIGNATURE
; a string in the form of a D-Bus type signature.?
: the type string ofG_VARIANT_TYPE_BASIC
; an indefinite type that is a supertype of any of the basic types.v
: the type string ofG_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 ofG_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 ofG_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.
Synopsis
- newtype VariantType = VariantType (ManagedPtr VariantType)
- noVariantType :: Maybe VariantType
- variantTypeChecked_ :: (HasCallStack, MonadIO m) => Text -> m VariantType
- variantTypeCopy :: (HasCallStack, MonadIO m) => VariantType -> m VariantType
- variantTypeDupString :: (HasCallStack, MonadIO m) => VariantType -> m Text
- variantTypeElement :: (HasCallStack, MonadIO m) => VariantType -> m VariantType
- variantTypeEqual :: (HasCallStack, MonadIO m) => VariantType -> VariantType -> m Bool
- variantTypeFirst :: (HasCallStack, MonadIO m) => VariantType -> m VariantType
- variantTypeFree :: (HasCallStack, MonadIO m) => VariantType -> m ()
- variantTypeGetStringLength :: (HasCallStack, MonadIO m) => VariantType -> m Word64
- variantTypeHash :: (HasCallStack, MonadIO m) => VariantType -> m Word32
- variantTypeIsArray :: (HasCallStack, MonadIO m) => VariantType -> m Bool
- variantTypeIsBasic :: (HasCallStack, MonadIO m) => VariantType -> m Bool
- variantTypeIsContainer :: (HasCallStack, MonadIO m) => VariantType -> m Bool
- variantTypeIsDefinite :: (HasCallStack, MonadIO m) => VariantType -> m Bool
- variantTypeIsDictEntry :: (HasCallStack, MonadIO m) => VariantType -> m Bool
- variantTypeIsMaybe :: (HasCallStack, MonadIO m) => VariantType -> m Bool
- variantTypeIsSubtypeOf :: (HasCallStack, MonadIO m) => VariantType -> VariantType -> m Bool
- variantTypeIsTuple :: (HasCallStack, MonadIO m) => VariantType -> m Bool
- variantTypeIsVariant :: (HasCallStack, MonadIO m) => VariantType -> m Bool
- variantTypeKey :: (HasCallStack, MonadIO m) => VariantType -> m VariantType
- variantTypeNItems :: (HasCallStack, MonadIO m) => VariantType -> m Word64
- variantTypeNew :: (HasCallStack, MonadIO m) => Text -> m VariantType
- variantTypeNewArray :: (HasCallStack, MonadIO m) => VariantType -> m VariantType
- variantTypeNewDictEntry :: (HasCallStack, MonadIO m) => VariantType -> VariantType -> m VariantType
- variantTypeNewMaybe :: (HasCallStack, MonadIO m) => VariantType -> m VariantType
- variantTypeNewTuple :: (HasCallStack, MonadIO m) => [VariantType] -> m VariantType
- variantTypeNext :: (HasCallStack, MonadIO m) => VariantType -> m VariantType
- variantTypeStringGetDepth_ :: (HasCallStack, MonadIO m) => Text -> m Word64
- variantTypeStringIsValid :: (HasCallStack, MonadIO m) => Text -> m Bool
- variantTypeStringScan :: (HasCallStack, MonadIO m) => Text -> Maybe Text -> m (Bool, Text)
- variantTypeValue :: (HasCallStack, MonadIO m) => VariantType -> m VariantType
Exported types
newtype VariantType Source #
Memory-managed wrapper type.
Instances
BoxedObject VariantType Source # | |
Defined in GI.GLib.Structs.VariantType boxedType :: VariantType -> IO GType # |
noVariantType :: Maybe VariantType Source #
A convenience alias for Nothing
:: Maybe
VariantType
.
Methods
checked_
variantTypeChecked_ :: (HasCallStack, MonadIO m) => Text -> m VariantType Source #
No description available in the introspection data.
copy
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m VariantType | Returns: a new Since 2.24 |
Makes a copy of a VariantType
. It is appropriate to call
variantTypeFree
on the return value. type
may not be Nothing
.
dupString
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m Text | Returns: the corresponding type string Since 2.24 |
Returns a newly-allocated copy of the type string corresponding to
type
. The returned string is nul-terminated. It is appropriate to
call free
on the return value.
element
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m VariantType | Returns: the element type of Since 2.24 |
Determines the element type of an array or maybe type.
This function may only be used with array or maybe types.
equal
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> VariantType |
|
-> m Bool | Returns: Since 2.24 |
Compares type1
and type2
for equality.
Only returns True
if the types are exactly equal. Even if one type
is an indefinite type and the other is a subtype of it, False
will
be returned if they are not exactly equal. If you want to check for
subtypes, use variantTypeIsSubtypeOf
.
The argument types of type1
and type2
are only gconstpointer
to
allow use with HashTable
without function pointer casting. For
both arguments, a valid VariantType
must be provided.
first
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m VariantType | Returns: the first item type of Since 2.24 |
Determines the first item type of a tuple or dictionary entry type.
This function may only be used with tuple or dictionary entry types,
but must not be used with the generic tuple type
G_VARIANT_TYPE_TUPLE
.
In the case of a dictionary entry type, this returns the type of the key.
Nothing
is returned in case of type
being G_VARIANT_TYPE_UNIT
.
This call, together with variantTypeNext
provides an iterator
interface over tuple and dictionary entry types.
free
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m () |
Frees a VariantType
that was allocated with
variantTypeCopy
, variantTypeNew
or one of the container
type constructor functions.
In the case that type
is Nothing
, this function does nothing.
Since 2.24
getStringLength
variantTypeGetStringLength Source #
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m Word64 | Returns: the length of the corresponding type string Since 2.24 |
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()
.
hash
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m Word32 | Returns: the hash value Since 2.24 |
Hashes type
.
The argument type of type
is only gconstpointer
to allow use with
HashTable
without function pointer casting. A valid
VariantType
must be provided.
isArray
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m Bool | Returns: Since 2.24 |
Determines if the given type
is an array type. This is true if the
type string for type
starts with an 'a'.
This function returns True
for any indefinite type for which every
definite subtype is an array type -- G_VARIANT_TYPE_ARRAY
, for
example.
isBasic
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m Bool | Returns: Since 2.24 |
Determines if the given type
is a basic type.
Basic types are booleans, bytes, integers, doubles, strings, object paths and signatures.
Only a basic type may be used as the key of a dictionary entry.
This function returns False
for all indefinite types except
G_VARIANT_TYPE_BASIC
.
isContainer
variantTypeIsContainer Source #
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m Bool | Returns: Since 2.24 |
Determines if the given type
is a container type.
Container types are any array, maybe, tuple, or dictionary entry types plus the variant type.
This function returns True
for any indefinite type for which every
definite subtype is a container -- G_VARIANT_TYPE_ARRAY
, for
example.
isDefinite
variantTypeIsDefinite Source #
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m Bool | Returns: Since 2.24 |
Determines if the given type
is definite (ie: not indefinite).
A type is definite if its type string does not contain any indefinite type characters ('*', '?', or 'r').
A GVariant
instance may not have an indefinite type, so calling
this function on the result of variantGetType
will always
result in True
being returned. Calling this function on an
indefinite type like G_VARIANT_TYPE_ARRAY
, however, will result in
False
being returned.
isDictEntry
variantTypeIsDictEntry Source #
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m Bool | Returns: Since 2.24 |
Determines if the given type
is a dictionary entry type. This is
true if the type string for type
starts with a '{'.
This function returns True
for any indefinite type for which every
definite subtype is a dictionary entry type --
G_VARIANT_TYPE_DICT_ENTRY
, for example.
isMaybe
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m Bool | Returns: Since 2.24 |
Determines if the given type
is a maybe type. This is true if the
type string for type
starts with an 'm'.
This function returns True
for any indefinite type for which every
definite subtype is a maybe type -- G_VARIANT_TYPE_MAYBE
, for
example.
isSubtypeOf
variantTypeIsSubtypeOf Source #
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> VariantType |
|
-> m Bool | Returns: Since 2.24 |
Checks if type
is a subtype of supertype
.
This function returns True
if type
is a subtype of supertype
. All
types are considered to be subtypes of themselves. Aside from that,
only indefinite types can have subtypes.
isTuple
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m Bool | Returns: Since 2.24 |
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
.
This function returns True
for any indefinite type for which every
definite subtype is a tuple type -- G_VARIANT_TYPE_TUPLE
, for
example.
isVariant
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m Bool | Returns: Since 2.24 |
Determines if the given type
is the variant type.
key
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m VariantType | Returns: the key type of the dictionary entry Since 2.24 |
Determines the key type of a dictionary entry type.
This function may only be used with a dictionary entry type. Other
than the additional restriction, this call is equivalent to
variantTypeFirst
.
nItems
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m Word64 | Returns: the number of items in Since 2.24 |
Determines the number of items contained in a tuple or dictionary entry type.
This function may only be used with tuple or dictionary entry types,
but must not be used with the generic tuple type
G_VARIANT_TYPE_TUPLE
.
In the case of a dictionary entry type, this function will always return 2.
new
:: (HasCallStack, MonadIO m) | |
=> Text |
|
-> m VariantType | Returns: a new |
Creates a new VariantType
corresponding to the type string given
by typeString
. It is appropriate to call variantTypeFree
on
the return value.
It is a programmer error to call this function with an invalid type
string. Use variantTypeStringIsValid
if you are unsure.
Since: 2.24
newArray
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m VariantType | Returns: a new array Since 2.24 |
Constructs the type corresponding to an array of elements of the
type type
.
It is appropriate to call variantTypeFree
on the return value.
newDictEntry
variantTypeNewDictEntry Source #
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> VariantType |
|
-> m VariantType | Returns: a new dictionary entry Since 2.24 |
Constructs the type corresponding to a dictionary entry with a key
of type key
and a value of type value
.
It is appropriate to call variantTypeFree
on the return value.
newMaybe
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m VariantType | Returns: a new maybe Since 2.24 |
Constructs the type corresponding to a maybe instance containing
type type
or Nothing.
It is appropriate to call variantTypeFree
on the return value.
newTuple
:: (HasCallStack, MonadIO m) | |
=> [VariantType] |
|
-> m VariantType | Returns: a new tuple Since 2.24 |
Constructs a new tuple type, from items
.
length
is the number of items in items
, or -1 to indicate that
items
is Nothing
-terminated.
It is appropriate to call variantTypeFree
on the return value.
next
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m VariantType | Returns: the next Since 2.24 |
Determines the next item type of a tuple or dictionary entry type.
type
must be the result of a previous call to
variantTypeFirst
or variantTypeNext
.
If called on the key type of a dictionary entry then this call
returns the value type. If called on the value type of a dictionary
entry then this call returns Nothing
.
For tuples, Nothing
is returned when type
is the last item in a tuple.
stringGetDepth_
variantTypeStringGetDepth_ :: (HasCallStack, MonadIO m) => Text -> m Word64 Source #
No description available in the introspection data.
stringIsValid
variantTypeStringIsValid Source #
:: (HasCallStack, MonadIO m) | |
=> Text |
|
-> m Bool | Returns: Since 2.24 |
Checks if typeString
is a valid GVariant type string. This call is
equivalent to calling variantTypeStringScan
and confirming
that the following character is a nul terminator.
stringScan
variantTypeStringScan Source #
:: (HasCallStack, MonadIO m) | |
=> Text |
|
-> Maybe Text |
|
-> m (Bool, Text) | Returns: |
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.
If a valid type string is found, endptr
is updated to point to the
first character past the end of the string that was found and True
is returned.
If there is no valid type string starting at string
, or if the type
string does not end before limit
then False
is returned.
For the simple case of checking if a string is a valid type string,
see variantTypeStringIsValid
.
Since: 2.24
value
:: (HasCallStack, MonadIO m) | |
=> VariantType |
|
-> m VariantType | Returns: the value type of the dictionary entry Since 2.24 |
Determines the value type of a dictionary entry type.
This function may only be used with a dictionary entry type.