/usr/include/glibmm-2.4/glibmm/variant.h is in libglibmm-2.4-dev 2.50.0-1.
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#ifndef _GLIBMM_VARIANT_H
#define _GLIBMM_VARIANT_H
/* Copyright 2010 The glibmm Development Team
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free
* Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
#include <glibmmconfig.h>
#include <glibmm/varianttype.h>
#include <glibmm/variantiter.h>
#include <glibmm/refptr.h>
#include <glibmm/ustring.h>
#include <glibmm/error.h>
#include <utility>
#include <vector>
#include <map>
#include <stdexcept>
#include <typeinfo>
namespace Glib
{
class Bytes;
/** @defgroup Variant Variant Data Types
*
* The Variant classes deal with strongly typed
* variant data. A Variant stores a value along with
* information about the type of that value. The range of possible
* values is determined by the type. The type system used is VariantType.
*
* See the VariantBase class and its derived types, such as VariantContainerBase,
* and the Variant<> template type.
*
* Variant instances always have a type and a value (which are given
* at construction time). The type and value of a Variant
* can never change other than by the Variant itself being
* destroyed. A Variant cannot contain a pointer.
*
* Variant is heavily optimised for dealing with data in serialised
* form. It works particularly well with data located in memory-mapped
* files. It can perform nearly all deserialisation operations in a
* small constant time, usually touching only a single memory page.
* Serialised Variant data can also be sent over the network.
*
* Variant is largely compatible with D-Bus. Almost all types of
* Variant instances can be sent over D-Bus. See VariantType for
* exceptions.
*
* There is a Python-inspired text language for describing Variant
* values. Variant includes a printer for this language and a parser
* with type inferencing.
*/
//Note: We wrap this because it is thrown by GtkBuilder's functions.
// See https://bugzilla.gnome.org/show_bug.cgi?id=708206
// It would also be thrown by parse() if we wrap g_variant_parse().
// Now (2014-01-30) it's also thrown by Gio::Action::parse_detailed_name().
/** %Exception class for Variant parse errors.
*/
class VariantParseError : public Glib::Error
{
public:
/** @var Code FAILED
* Generic error (unused).
*
* @var Code BASIC_TYPE_EXPECTED
* A non-basic VariantType was given where a basic type was expected.
*
* @var Code CANNOT_INFER_TYPE
* Cannot infer the VariantType.
*
* @var Code DEFINITE_TYPE_EXPECTED
* An indefinite VariantType was given where a definite type was expected.
*
* @var Code INPUT_NOT_AT_END
* Extra data after parsing finished.
*
* @var Code INVALID_CHARACTER
* Invalid character in number or unicode escape.
*
* @var Code INVALID_FORMAT_STRING
* Not a valid Variant format string.
*
* @var Code INVALID_OBJECT_PATH
* Not a valid object path.
*
* @var Code INVALID_SIGNATURE
* Not a valid type signature.
*
* @var Code INVALID_TYPE_STRING
* Not a valid Variant type string.
*
* @var Code NO_COMMON_TYPE
* Could not find a common type for array entries.
*
* @var Code NUMBER_OUT_OF_RANGE
* The numerical value is out of range of the given type.
*
* @var Code NUMBER_TOO_BIG
* The numerical value is out of range for any type.
*
* @var Code TYPE_ERROR
* Cannot parse as variant of the specified type.
*
* @var Code UNEXPECTED_TOKEN
* An unexpected token was encountered.
*
* @var Code UNKNOWN_KEYWORD
* An unknown keyword was encountered.
*
* @var Code UNTERMINATED_STRING_CONSTANT
* Unterminated string constant.
*
* @var Code VALUE_EXPECTED
* No value given.
*
* @enum Code
*
* %Error codes returned by parsing text-format GVariants.
*/
enum Code
{
FAILED,
BASIC_TYPE_EXPECTED,
CANNOT_INFER_TYPE,
DEFINITE_TYPE_EXPECTED,
INPUT_NOT_AT_END,
INVALID_CHARACTER,
INVALID_FORMAT_STRING,
INVALID_OBJECT_PATH,
INVALID_SIGNATURE,
INVALID_TYPE_STRING,
NO_COMMON_TYPE,
NUMBER_OUT_OF_RANGE,
NUMBER_TOO_BIG,
TYPE_ERROR,
UNEXPECTED_TOKEN,
UNKNOWN_KEYWORD,
UNTERMINATED_STRING_CONSTANT,
VALUE_EXPECTED
};
VariantParseError(Code error_code, const Glib::ustring& error_message);
explicit VariantParseError(GError* gobject);
Code code() const;
#ifndef DOXYGEN_SHOULD_SKIP_THIS
private:
static void throw_func(GError* gobject);
friend void wrap_init(); // uses throw_func()
#endif //DOXYGEN_SHOULD_SKIP_THIS
};
//TODO: Add this documentation from the API if we are confident of it for the C++ wrapper:
// #GVariant is completely threadsafe. A #GVariant instance can be
// concurrently accessed in any way from any number of threads without
// problems.
// Note that we don't copy GVariant's documentation about Memory Use because
// it seems easy to get out of sync and people can look at that C documentation if necessary.
/** This is the base class for all Variant types.
*
* If the actual type is known at compile-time then you should use a specific
* Variant<>, such as Variant<int>. Otherwise, you may use get_type(),
* is_of_type(), or cast_dynamic().
*
* @newin{2,28}
* @ingroup Variant
*/
class VariantBase
{
public:
#ifndef DOXYGEN_SHOULD_SKIP_THIS
using CppObjectType = VariantBase;
using BaseObjectType = GVariant;
#endif /* DOXYGEN_SHOULD_SKIP_THIS */
/** Constructs an invalid object.
* E.g. for output arguments to methods. There is not much you can do with
* the object before it has been assigned a valid value.
*/
VariantBase();
// Use make_a_copy=true when getting it directly from a struct.
explicit VariantBase(GVariant* castitem, bool make_a_copy = false);
VariantBase(const VariantBase& src);
VariantBase& operator=(const VariantBase& src);
VariantBase(VariantBase&& other) noexcept;
VariantBase& operator=(VariantBase&& other) noexcept;
~VariantBase() noexcept;
void swap(VariantBase& other) noexcept;
GVariant* gobj() { return gobject_; }
const GVariant* gobj() const { return gobject_; }
///Provides access to the underlying C instance. The caller is responsible for freeing it. Use when directly setting fields in structs.
GVariant* gobj_copy() const;
protected:
GVariant* gobject_;
private:
public:
#ifndef GLIBMM_DISABLE_DEPRECATED
/** This typedef is just to make it more obvious that
* our operator const void* should be used like operator bool().
*
* @deprecated Use the explicit operator bool() instead.
*/
using BoolExpr = const void*;
/** Test whether the Variant has an underlying instance.
*
* Mimics usage of pointers:
* @code
* if (variant)
* do_something();
* @endcode
*
* @deprecated Use the explicit operator bool() instead.
*
* @newin{2,36}
*/
operator BoolExpr() const;
#endif // GLIBMM_DISABLE_DEPRECATED
/** Test whether the Variant has an underlying instance.
*
* @newin{2,50}
*/
explicit operator bool() const;
/** Replace the underlying GVariant.
* This is for use by methods that take a VariantBase& as an output
* parameter.
*
* @param cobject The GVariant* obtained from a C function.
* @param take_a_reference Whether this method should take a reference, for
* instance if the C function has not given one.
*/
void init(const GVariant* cobject, bool take_a_reference = false);
// It's necessary to take an extra reference of the 'const GVariantType*'
// returned by g_variant_get_type() because it doesn't do that already.
/** Determines the type of @a value.
*
* The return value is valid for the lifetime of @a value and must not
* be freed.
*
* @newin{2,24}
*
* @return A VariantType.
*/
VariantType get_type() const;
/** Returns the type string of @a value. Unlike the result of calling
* g_variant_type_peek_string(), this string is nul-terminated. This
* string belongs to Variant and must not be freed.
*
* @newin{2,24}
*
* @return The type string for the type of @a value.
*/
std::string get_type_string() const;
/** Checks whether @a value has a floating reference count.
*
* This function should only ever be used to assert that a given variant
* is or is not floating, or for debug purposes. To acquire a reference
* to a variant that might be floating, always use g_variant_ref_sink()
* or g_variant_take_ref().
*
* See g_variant_ref_sink() for more information about floating reference
* counts.
*
* @newin{2,26}
*
* @return Whether @a value is floating.
*/
bool is_floating() const;
/** Checks if a value has a type matching the provided type.
*
* @newin{2,24}
*
* @param type A VariantType.
* @return <tt>true</tt> if the type of @a value matches @a type.
*/
bool is_of_type(const VariantType& type) const;
/** Checks if @a value is a container.
*
* @newin{2,24}
*
* @return <tt>true</tt> if @a value is a container.
*/
bool is_container() const;
/** Classifies @a value according to its top-level type.
*
* @newin{2,24}
*
* @return The VariantClass of @a value.
*/
GVariantClass classify() const;
/** Determines the number of bytes that would be required to store @a value
* with g_variant_store().
*
* If @a value has a fixed-sized type then this function always returned
* that fixed size.
*
* In the case that @a value is already in serialised form or the size has
* already been calculated (ie: this function has been called before)
* then this function is O(1). Otherwise, the size is calculated, an
* operation which is approximately O(n) in the number of values
* involved.
*
* @newin{2,24}
*
* @return The serialised size of @a value.
*/
gsize get_size() const;
#ifndef GLIBMM_DISABLE_DEPRECATED
/** Returns a pointer to the serialised form of a Variant instance.
* The returned data may not be in fully-normalised form if read from an
* untrusted source. The returned data must not be freed; it remains
* valid for as long as @a value exists.
*
* If @a value is a fixed-sized value that was deserialised from a
* corrupted serialised container then <tt>nullptr</tt> may be returned. In this
* case, the proper thing to do is typically to use the appropriate
* number of nul bytes in place of @a value. If @a value is not fixed-sized
* then <tt>nullptr</tt> is never returned.
*
* In the case that @a value is already in serialised form, this function
* is O(1). If the value is not already in serialised form,
* serialisation occurs implicitly and is approximately O(n) in the size
* of the result.
*
* To deserialise the data returned by this function, in addition to the
* serialised data, you must know the type of the Variant, and (if the
* machine might be different) the endianness of the machine that stored
* it. As a result, file formats or network messages that incorporate
* serialised Variants must include this information either
* implicitly (for instance "the file always contains a
* VARIANT_TYPE_VARIANT and it is always in little-endian order") or
* explicitly (by storing the type and/or endianness in addition to the
* serialised data).
*
* @newin{2,24}
*
* @deprecated Use the const version instead.
*
* @return The serialised form of @a value, or <tt>nullptr</tt>.
*/
gconstpointer get_data();
#endif // GLIBMM_DISABLE_DEPRECATED
/** Returns a pointer to the serialised form of a Variant instance.
* The returned data may not be in fully-normalised form if read from an
* untrusted source. The returned data must not be freed; it remains
* valid for as long as @a value exists.
*
* If @a value is a fixed-sized value that was deserialised from a
* corrupted serialised container then <tt>nullptr</tt> may be returned. In this
* case, the proper thing to do is typically to use the appropriate
* number of nul bytes in place of @a value. If @a value is not fixed-sized
* then <tt>nullptr</tt> is never returned.
*
* In the case that @a value is already in serialised form, this function
* is O(1). If the value is not already in serialised form,
* serialisation occurs implicitly and is approximately O(n) in the size
* of the result.
*
* To deserialise the data returned by this function, in addition to the
* serialised data, you must know the type of the Variant, and (if the
* machine might be different) the endianness of the machine that stored
* it. As a result, file formats or network messages that incorporate
* serialised Variants must include this information either
* implicitly (for instance "the file always contains a
* VARIANT_TYPE_VARIANT and it is always in little-endian order") or
* explicitly (by storing the type and/or endianness in addition to the
* serialised data).
*
* @newin{2,46}
*
* @return The serialised form of @a value, or <tt>nullptr</tt>.
*/
gconstpointer get_data() const;
/** Returns a pointer to the serialised form of a Variant instance.
* The semantics of this function are exactly the same as
* g_variant_get_data(), except that the returned Bytes holds
* a reference to the variant data.
*
* @newin{2,46}
*
* @return A new Bytes representing the variant data.
*/
Glib::RefPtr<const Glib::Bytes> get_data_as_bytes() const;
/** Stores the serialised form of @a value at @a data. @a data should be
* large enough. See g_variant_get_size().
*
* The stored data is in machine native byte order but may not be in
* fully-normalised form if read from an untrusted source. See
* g_variant_get_normal_form() for a solution.
*
* As with g_variant_get_data(), to be able to deserialise the
* serialised variant successfully, its type and (if the destination
* machine might be different) its endianness must also be available.
*
* This function is approximately O(n) in the size of @a data.
*
* @newin{2,24}
*
* @param data The location to store the serialised data at.
*/
void store(gpointer data) const;
/** Pretty-prints @a value in the format understood by g_variant_parse().
*
* The format is described [here][gvariant-text].
*
* If @a type_annotate is <tt>true</tt>, then type information is included in
* the output.
*
* @newin{2,24}
*
* @param type_annotate <tt>true</tt> if type information should be included in
* the output.
* @return A newly-allocated string holding the result.
*/
Glib::ustring print(bool type_annotate = false) const;
/** Generates a hash value for a Variant instance.
*
* The output of this function is guaranteed to be the same for a given
* value only per-process. It may change between different processor
* architectures or even different versions of GLib. Do not use this
* function as a basis for building protocols or file formats.
*
* The type of @a value is #gconstpointer only to allow use of this
* function with HashTable. @a value must be a Variant.
*
* @newin{2,24}
*
* @return A hash value corresponding to @a value.
*/
guint hash() const;
/** Checks if @a *this and @a other have the same type and value.
*
* @newin{2,24}
*
* @param other The Variant to compare with.
* @return <tt>true</tt> if @a *this and @a other are equal.
*/
bool equal(const VariantBase& other) const;
/** Gets a VariantBase instance that has the same value as this variant and
* is trusted to be in normal form.
*
* If this variant is already trusted to be in normal form then a new
* reference to the variant is returned.
*
* If this variant is not already trusted, then it is scanned to check if it
* is in normal form. If it is found to be in normal form then it is marked
* as trusted and a new reference to it is returned.
*
* If this variant is found not to be in normal form then a new trusted
* VariantBase is created with the same value as this variant.
*
* It makes sense to call this function if you've received variant data from
* untrusted sources and you want to ensure your serialised output is
* definitely in normal form.
*
* @param result A location in which to store the trusted VariantBase.
* @newin{2,24}
*/
void get_normal_form(VariantBase& result) const;
/** Checks if @a value is in normal form.
*
* The main reason to do this is to detect if a given chunk of
* serialised data is in normal form: load the data into a Variant
* using g_variant_new_from_data() and then use this function to
* check.
*
* If @a value is found to be in normal form then it will be marked as
* being trusted. If the value was already marked as being trusted then
* this function will immediately return <tt>true</tt>.
*
* @newin{2,24}
*
* @return <tt>true</tt> if @a value is in normal form.
*/
bool is_normal_form() const;
/** Performs a byteswapping operation on the contents of this variant. The
* result is that all multi-byte numeric data contained in the variant is
* byteswapped. That includes 16, 32, and 64bit signed and unsigned integers
* as well as file handles and double precision floating point values.
*
* This function is an identity mapping on any value that does not contain
* multi-byte numeric data. That include strings, booleans, bytes and
* containers containing only these things (recursively).
*
* The returned value is always in normal form and is marked as trusted.
*
* @param result A location in which to store the byteswapped form of this
* variant.
* @newin{2,24}
*/
void byteswap(VariantBase& result) const;
/** Checks if calling g_variant_get() with @a format_string on @a value would
* be valid from a type-compatibility standpoint. @a format_string is
* assumed to be a valid format string (from a syntactic standpoint).
*
* If @a copy_only is <tt>true</tt> then this function additionally checks that it
* would be safe to call g_variant_unref() on @a value immediately after
* the call to g_variant_get() without invalidating the result. This is
* only possible if deep copies are made (ie: there are no pointers to
* the data inside of the soon-to-be-freed Variant instance). If this
* check fails then a g_critical() is printed and <tt>false</tt> is returned.
*
* This function is meant to be used by functions that wish to provide
* varargs accessors to Variant values of uncertain values (eg:
* g_variant_lookup() or Glib::menu_model_get_item_attribute()).
*
* @newin{2,34}
*
* @param format_string A valid Variant format string.
* @param copy_only <tt>true</tt> to ensure the format string makes deep copies.
* @return <tt>true</tt> if @a format_string is safe to use.
*/
bool check_format_string(const std::string& format_string, bool copy_only = false) const;
//Ignore private API from gvariant-core.h:
/** Cast to a specific variant type.
* For instance:
* @code
* Variant<std::string> derived = VariantBase::cast_dynamic< Variant<std::string> >(base);
* @endcode
*
* @param v The variant to cast to a specific type.
* @result The variant as a specific type.
* @throws std::bad_cast if the Variant was not of the expected type.
*/
template<class V_CastTo>
static V_CastTo cast_dynamic(const VariantBase& v) throw(std::bad_cast);
protected:
#ifndef DOXYGEN_SHOULD_SKIP_THIS
/** Used by cast_dynamic().
* In addition to an exact match, the following casts are possible:
* - VARIANT_TYPE_OBJECT_PATH and VARIANT_TYPE_SIGNATURE can be cast to
* VARIANT_TYPE_STRING (Glib::ustring).
* - VARIANT_TYPE_STRING, VARIANT_TYPE_OBJECT_PATH and VARIANT_TYPE_SIGNATURE
* can be cast to VARIANT_TYPE_BYTESTRING (std::string).
* - VARIANT_TYPE_HANDLE can be cast to VARIANT_TYPE_INT32.
*
* These casts are possible also when they are parts of a more complicated type.
* E.g. in Variant<std::map<Glib::ustring, std::vector<std::string> > > the map's keys
* can be VARIANT_TYPE_OBJECT_PATH and the vector's elements can be VARIANT_TYPE_SIGNATURE.
* @newin{2,46}
*/
bool is_castable_to(const VariantType& supertype) const;
#endif //DOXYGEN_SHOULD_SKIP_THIS
private:
/** Relational operators are deleted to prevent invalid conversion
* to const void*.
*/
bool operator<(const VariantBase& src) const;
/// See operator<().
bool operator<=(const VariantBase& src) const;
/// See operator<().
bool operator>(const VariantBase& src) const;
/// See operator<().
bool operator>=(const VariantBase& src) const;
/// See operator<().
bool operator==(const VariantBase& src) const;
/// See operator<().
bool operator!=(const VariantBase& src) const;
};
template<class V_CastTo>
V_CastTo VariantBase::cast_dynamic(const VariantBase& v)
throw(std::bad_cast)
{
if(!(v.gobj()))
{
return V_CastTo();
}
if(v.is_castable_to(V_CastTo::variant_type()))
{
return V_CastTo(const_cast<GVariant*>(v.gobj()), true);
}
else
{
throw std::bad_cast();
}
}
/** Base class from which string variant classes derive.
* @newin{2,28}
* @ingroup Variant
*/
class VariantStringBase : public VariantBase
{
// Trick gmmproc into thinking this is derived from GVariant to wrap some methods.
public:
#ifndef DOXYGEN_SHOULD_SKIP_THIS
using CppObjectType = VariantStringBase;
using BaseObjectType = GVariant;
#endif /* DOXYGEN_SHOULD_SKIP_THIS */
private:
public:
using CType = GVariant*;
using CppType = VariantStringBase;
/// Default constructor.
VariantStringBase();
/** GVariant constructor.
* @param castitem The GVariant to wrap.
* @param take_a_reference Whether to take an extra reference of the
* GVariant or not (not taking one could destroy the GVariant with the
* wrapper).
*/
explicit VariantStringBase(GVariant* castitem, bool take_a_reference = false);
/** Creates a D-Bus object path variant with the contents of @a string. @a
* string must be a valid D-Bus object path. Use is_object_path() if unsure.
*
* @param output A location in which to store the new object path variant
* instance.
* @param object_path A normal nul-terminated string.
* @newin{2,28}
*/
static void create_object_path(VariantStringBase& output,
const std::string& object_path);
/** Determines if a given string is a valid D-Bus object path. You
* should ensure that a string is a valid D-Bus object path before
* passing it to g_variant_new_object_path().
*
* A valid object path starts with '/' followed by zero or more
* sequences of characters separated by '/' characters. Each sequence
* must contain only the characters "[A-Z][a-z][0-9]_". No sequence
* (including the one following the final '/' character) may be empty.
*
* @newin{2,24}
*
* @param string A normal C nul-terminated string.
* @return <tt>true</tt> if @a string is a D-Bus object path.
*/
static bool is_object_path(const std::string& string);
/** Creates a D-Bus type signature variant with the contents of @a string. @a
* string must be a valid D-Bus type signature. Use is_signature() if unsure.
*
* @param output A location in which to store the new signature variant
* instance.
* @param signature A normal nul-terminated string.
* @newin{2,28}
*/
static void create_signature(VariantStringBase& output,
const std::string& signature);
/** Determines if a given string is a valid D-Bus type signature. You
* should ensure that a string is a valid D-Bus type signature before
* passing it to g_variant_new_signature().
*
* D-Bus type signatures consist of zero or more definite VariantType
* strings in sequence.
*
* @newin{2,24}
*
* @param string A normal C nul-terminated string.
* @return <tt>true</tt> if @a string is a D-Bus type signature.
*/
static bool is_signature(const std::string& string);
};
/** The base class from which multiple-item Variants derive, such as Variants
* containing tuples or arrays.
*
* @newin{2,28}
* @ingroup Variant
*/
class VariantContainerBase : public VariantBase
{
// Trick gmmproc into thinking this is derived from GVariant to wrap some methods.
public:
#ifndef DOXYGEN_SHOULD_SKIP_THIS
using CppObjectType = VariantContainerBase;
using BaseObjectType = GVariant;
#endif /* DOXYGEN_SHOULD_SKIP_THIS */
private:
public:
using CType = GVariant*;
using CppType = VariantContainerBase;
/// Default constructor.
VariantContainerBase();
/** GVariant constructor.
* @param castitem The GVariant to wrap.
* @param take_a_reference Whether to take an extra reference of the
* GVariant or not (not taking one could destroy the GVariant with the
* wrapper).
*/
explicit VariantContainerBase(GVariant* castitem, bool take_a_reference = false);
/** Create a tuple variant from a vector of its variant children.
* @param children The vector containing the children of the container.
* @return The newly created tuple variant (as a VariantContainerBase).
*/
static VariantContainerBase create_tuple(const std::vector<VariantBase>& children);
/** Create a tuple variant with a single variant child.
* @param child The child variant.
* @return The newly created tuple variant (as a VariantContainerBase).
*/
static VariantContainerBase create_tuple(const VariantBase& child);
/** Depending on if @a child is <tt>nullptr</tt>, either wraps @a child inside of a
* maybe container or creates a Nothing instance for the given @a type.
*
* At least one of @a child_type and @a child must be non-<tt>nullptr</tt>.
* If @a child_type is non-<tt>nullptr</tt> then it must be a definite type.
* If they are both non-<tt>nullptr</tt> then @a child_type must be the type
* of @a child.
*
* If @a child is a floating reference (see g_variant_ref_sink()), the new
* instance takes ownership of @a child.
*
* @newin{2,24}
*
* @param child_type The VariantType of the child, or <tt>nullptr</tt>.
* @param child The child value, or <tt>nullptr</tt>.
* @return A floating reference to a new Variant maybe instance.
*/
static VariantContainerBase create_maybe(const VariantType& child_type,
const VariantBase& child = VariantBase());
/** Determines the number of children in a container Variant instance.
* This includes variants, maybes, arrays, tuples and dictionary
* entries. It is an error to call this function on any other type of
* Variant.
*
* For variants, the return value is always 1. For values with maybe
* types, it is always zero or one. For arrays, it is the length of the
* array. For tuples it is the number of tuple items (which depends
* only on the type). For dictionary entries, it is always 2
*
* This function is O(1).
*
* @newin{2,24}
*
* @return The number of children in the container.
*/
gsize get_n_children() const;
/** Reads a child item out of this instance. This method is valid for
* variants, maybes, arrays, tuples and dictionary entries.
*
* It is an error if @a index is greater than the number of child items in
* the container. See get_n_children().
*
* This function is O(1).
*
* @param index The index of the child to fetch.
* @param child A location in which to store the child at the specified
* index.
* @throw std::out_of_range
* @newin{2,28}
*/
void get_child(VariantBase& child, gsize index = 0) const;
/** Reads a child item out of a container Variant instance. This
* includes variants, maybes, arrays, tuples and dictionary
* entries. It is an error to call this function on any other type of
* Variant.
*
* It is an error if @a index is greater than the number of child items
* in the container. See g_variant_n_children().
*
* The returned value is never floating. You should free it with
* g_variant_unref() when you're done with it.
*
* This function is O(1).
*
* @newin{2,24}
*
* @param index The index of the child to fetch.
* @return The child at the specified index.
*/
VariantBase get_child(gsize index = 0);
/* TODO?:
/// A get() method to return the contents of the variant in the container.
template <class DataType>
DataType get_child(gsize index = 0) const;
*/
/** If this is a maybe-typed instance, extract its value. If the value is
* Nothing, then this function returns <tt>false</tt>.
*
* @param maybe A place in which to return the value (the value may be
* <tt>0</tt>).
* @newin{2,28}
*/
bool get_maybe(VariantBase& maybe) const;
protected:
#ifndef DOXYGEN_SHOULD_SKIP_THIS
/** Used by get_iter() in the subclasses.
* @newin{2,46}
*/
VariantIter get_iter(const VariantType& container_variant_type) const;
#endif //DOXYGEN_SHOULD_SKIP_THIS
};
template<>
VariantContainerBase VariantBase::cast_dynamic<VariantContainerBase>(const VariantBase& v)
throw(std::bad_cast);
/** Template class used for the specialization of the Variant<> classes.
* @newin{2,28}
* @ingroup Variant
*/
template<class T>
class Variant : public VariantBase
{
public:
using CppType = T;
};
/****************** Specializations ***********************************/
/** Specialization of Variant containing a VariantBase.
* @newin{2,28}
* @ingroup Variant
*/
template<>
class Variant<VariantBase> : public VariantContainerBase
{
// Trick gmmproc into thinking this is derived from GVariant to wrap some methods.
public:
#ifndef DOXYGEN_SHOULD_SKIP_THIS
using CppObjectType = Variant<VariantBase>;
using BaseObjectType = GVariant;
#endif /* DOXYGEN_SHOULD_SKIP_THIS */
private:
public:
using CType = GVariant*;
using CppType = VariantBase;
using CppContainerType = Variant<VariantBase>;
/// Default constructor.
Variant<VariantBase>();
/** GVariant constructor.
* @param castitem The GVariant to wrap.
* @param take_a_reference Whether to take an extra reference of the
* GVariant or not (not taking one could destroy the GVariant with the
* wrapper).
*/
explicit Variant<VariantBase>(GVariant* castitem, bool take_a_reference = false);
/** Gets the VariantType.
* @return The VariantType.
* @newin{2,28}
*/
static const VariantType& variant_type() G_GNUC_CONST;
//This must have a create() method because otherwise it would be a copy
//constructor.
/** Creates a new Variant<VariantBase>.
* @param data The value of the new Variant.
* @return The new Variant.
* @newin{2,28}
*/
static Variant<VariantBase> create(const VariantBase& data);
//TODO: Documentation
void get(VariantBase& variant) const;
//TODO: Deprecate this in favour of get(VariantBase&)?
/** Unboxes @a value. The result is the Variant instance that was
* contained in @a value.
*
* @newin{2,24}
*
* @return The item contained in the variant.
*/
VariantBase get() const;
};
/** Specialization of Variant containing a Variant<T>.
* @newin{2,36}
* @ingroup Variant
*/
template<class T>
class Variant< Variant<T> > : public VariantContainerBase
{
public:
using CType = GVariant*;
using CppType = Variant<T>;
using CppContainerType = Variant<CppType>;
/// Default constructor.
Variant< Variant<T> >();
/** GVariant constructor.
* @param castitem The GVariant to wrap.
* @param take_a_reference Whether to take an extra reference of the
* GVariant or not (not taking one could destroy the GVariant with the
* wrapper).
* @newin{2,36}
*/
explicit Variant< Variant<T> >(GVariant* castitem, bool take_a_reference = false);
/** Gets the VariantType.
* @return The VariantType.
* @newin{2,36}
*/
static const VariantType& variant_type() G_GNUC_CONST;
/** Creates a new Variant< Variant<T> >.
* @param data The value of the new Variant.
* @return The new Variant.
* @newin{2,36}
*/
static Variant< Variant<T> > create(const Variant<T>& data);
/** Gets the contents of the Variant.
* @return The contents of the Variant.
* @newin{2,36}
*/
Variant<T> get() const;
};
/** Specialization of Variant containing a Glib::ustring, for variants of type
* string, object path, or signature.
* @newin{2,28}
* @ingroup Variant
*/
template<>
class Variant<Glib::ustring> : public VariantStringBase
{
// Trick gmmproc into thinking this is derived from GVariant to wrap some methods.
public:
#ifndef DOXYGEN_SHOULD_SKIP_THIS
using CppObjectType = Variant<Glib::ustring>;
using BaseObjectType = GVariant;
#endif /* DOXYGEN_SHOULD_SKIP_THIS */
private:
public:
using CType = char*;
using CppType = Glib::ustring;
/// Default constructor.
Variant<Glib::ustring>();
/** GVariant constructor.
* @param castitem The GVariant to wrap.
* @param take_a_reference Whether to take an extra reference of the
* GVariant or not (not taking one could destroy the GVariant with the
* wrapper).
*/
explicit Variant<Glib::ustring>(GVariant* castitem, bool take_a_reference = false);
/** Gets the VariantType.
* @return The VariantType.
* @newin{2,28}
*/
static const VariantType& variant_type() G_GNUC_CONST;
/** Creates a new Variant<Glib::ustring>.
* @param data The value of the new Variant.
* @return The new Variant.
* @newin{2,28}
*/
static Variant<Glib::ustring> create(const Glib::ustring& data);
//We can't use WRAP_METHOD() here because g_variant_get_string() takes an extra length parameter.
/** Gets the contents of the Variant.
* @return The contents of the Variant.
* @newin{2,28}
*/
Glib::ustring get() const;
};
//TODO: When we can break ABI, remove this template specialization.
template<>
Variant<Glib::ustring> VariantBase::cast_dynamic< Variant<Glib::ustring> >(const VariantBase& v)
throw(std::bad_cast);
/** Specialization of Variant containing a std::string, for variants of type
* bytestring, string, object path, or signature.
* See also Variant<Glib::ustring> for UTF-8 strings.
* @newin{2,28}
* @ingroup Variant
*/
template<>
class Variant<std::string> : public VariantStringBase
{
// Trick gmmproc into thinking this is derived from GVariant to wrap some methods.
public:
#ifndef DOXYGEN_SHOULD_SKIP_THIS
using CppObjectType = Variant<std::string>;
using BaseObjectType = GVariant;
#endif /* DOXYGEN_SHOULD_SKIP_THIS */
private:
public:
using CType = char* ;
using CppType = std::string;
/// Default constructor.
Variant<std::string>();
/** GVariant constructor.
* @param castitem The GVariant to wrap.
* @param take_a_reference Whether to take an extra reference of the
* GVariant or not (not taking one could destroy the GVariant with the
* wrapper).
*/
explicit Variant<std::string>(GVariant* castitem, bool take_a_reference = false);
/** Gets the VariantType.
* @return The VariantType.
* @newin{2,28}
*/
static const VariantType& variant_type() G_GNUC_CONST;
/** Creates a new Variant<std::string>.
* @param data The value of the new Variant.
* @return The new Variant.
* @newin{2,28}
*/
static Variant<std::string> create(const std::string& data);
//TODO: Documentation.
std::string get() const;
};
//TODO: When we can break ABI, remove this template specialization.
template<>
Variant<std::string> VariantBase::cast_dynamic< Variant<std::string> >(const VariantBase& v)
throw(std::bad_cast);
/** Specialization of Variant containing a dictionary entry. See also
* Variant< std::map<K, V> >.
* @newin{2,28}
* @ingroup Variant
*/
template<class K, class V>
class Variant< std::pair<K, V> > : public VariantContainerBase
{
public:
using CppType = std::pair<K, V>;
using CppContainerType = Variant<CppType>;
/// Default constructor.
Variant< std::pair<K, V> >()
: VariantContainerBase()
{}
/** GVariant constructor.
* @param castitem The GVariant to wrap.
* @param take_a_reference Whether to take an extra reference of the
* GVariant or not (not taking one could destroy the GVariant with the
* wrapper).
*/
explicit Variant< std::pair<K, V> >(GVariant* castitem,
bool take_a_reference = false)
: VariantContainerBase(castitem, take_a_reference)
{}
/** Gets the VariantType.
* @return The VariantType.
* @newin{2,28}
*/
static const VariantType& variant_type() G_GNUC_CONST;
/** Creates a new Variant< std::pair<K, V> >.
* @param data The value of the new Variant.
* @return The new Variant.
* @newin{2,28}
*/
static Variant< std::pair<K, V> > create(const std::pair<K, V>& data);
/** Gets the contents of the Variant.
* @return The contents of the Variant.
* @throw std::out_of_range
* @newin{2,28}
*/
std::pair<K, V> get() const;
};
/** Specialization of Variant containing an array of items.
* @newin{2,28}
* @ingroup Variant
*/
template<class T>
class Variant< std::vector<T> > : public VariantContainerBase
{
public:
using CppType = T ;
using CppContainerType = std::vector<T>;
/// Default constructor.
Variant< std::vector<T> >()
: VariantContainerBase()
{}
/** GVariant constructor.
* @param castitem The GVariant to wrap.
* @param take_a_reference Whether to take an extra reference of the
* GVariant or not (not taking one could destroy the GVariant with the
* wrapper).
*/
explicit Variant< std::vector<T> >(GVariant* castitem,
bool take_a_reference = false)
: VariantContainerBase(castitem, take_a_reference)
{}
/** Gets the VariantType.
* @return The VariantType.
* @newin{2,28}
*/
static const VariantType& variant_type() G_GNUC_CONST;
/** Creates a new Variant from an array of numeric types.
* @param data The array to use for creation.
* @return The new Variant.
* @newin{2,28}
*/
static Variant< std::vector<T> > create(const std::vector<T>& data);
/** Gets a specific element of the array. It is an error if @a index is
* greater than the number of child items in the container. See
* VariantContainerBase::get_n_children().
*
* This function is O(1).
*
* @param index The index of the element.
* @return The element at index @a index.
* @throw std::out_of_range
* @newin{2,28}
*/
T get_child(gsize index) const;
/** Gets the vector of the Variant.
* @return The vector.
* @newin{2,28}
*/
std::vector<T> get() const;
/** Gets a VariantIter of the Variant.
* @return the VaraintIter.
* @newin{2,28}
*/
VariantIter get_iter() const;
};
/** Specialization of Variant containing an array of UTF-8 capable
* strings.
* @newin{2,28}
* @ingroup Variant
*/
template<>
class Variant< std::vector<Glib::ustring> > : public VariantContainerBase
{
public:
using CppType = Glib::ustring ;
using CppContainerType = std::vector<Glib::ustring>;
/// Default constructor.
Variant< std::vector<Glib::ustring> >();
/** GVariant constructor.
* @param castitem The GVariant to wrap.
* @param take_a_reference Whether to take an extra reference of the
* GVariant or not (not taking one could destroy the GVariant with the
* wrapper).
*/
explicit Variant< std::vector<Glib::ustring> >(GVariant* castitem, bool take_a_reference = false);
/** Gets the VariantType.
* @return The VariantType.
* @newin{2,28}
*/
static const VariantType& variant_type() G_GNUC_CONST;
/** Creates a new Variant from an array of strings.
* @param data The array to use for creation.
* @return The new Variant.
* @newin{2,28}
*/
static Variant< std::vector<Glib::ustring> >
create(const std::vector<Glib::ustring>& data);
/** Gets a specific element of the string array. It is an error if @a index
* is greater than the number of child items in the container. See
* VariantContainerBase::get_n_children().
*
* This function is O(1).
*
* @param index The index of the element.
* @return The element at index @a index.
* @throw std::out_of_range
* @newin{2,28}
*/
Glib::ustring get_child(gsize index) const;
/** Gets the string vector of the Variant.
* @return The vector.
* @newin{2,28}
*/
std::vector<Glib::ustring> get() const;
/** Gets a VariantIter of the Variant.
* @return the VaraintIter.
* @newin{2,28}
*/
VariantIter get_iter() const;
};
/** Specialization of Variant containing an array of non-UTF-8 strings
* (byte string arrays).
* @newin{2,28}
* @ingroup Variant
*/
template<>
class Variant< std::vector<std::string> > : public VariantContainerBase
{
public:
using CppType = std::string ;
using CppContainerType = std::vector<std::string>;
/// Default constructor.
Variant< std::vector<std::string> >();
/** GVariant constructor.
* @param castitem The GVariant to wrap.
* @param take_a_reference Whether to take an extra reference of the
* GVariant or not (not taking one could destroy the GVariant with the
* wrapper).
*/
explicit Variant< std::vector<std::string> >(GVariant* castitem, bool take_a_reference = false);
/** Gets the VariantType.
* @return The VariantType.
* @newin{2,28}
*/
static const VariantType& variant_type() G_GNUC_CONST;
/** Creates a new Variant from an array of strings.
* @param data The array to use for creation.
* @return The new Variant.
* @newin{2,28}
*/
static Variant< std::vector<std::string> >
create(const std::vector<std::string>& data);
/** Creates a new Variant from an array of D-Bus object paths.
* @param paths The array to use for creation.
* @return The new Variant.
* @newin{2,36}
*/
static Variant< std::vector<std::string> >
create_from_object_paths(const std::vector<std::string>& paths);
/** Gets a specific element of the string array. It is an error if @a index
* is greater than the number of child items in the container. See
* VariantContainerBase::get_n_children().
*
* This function is O(1).
*
* @param index The index of the element.
* @return The element at index @a index.
* @throw std::out_of_range
* @newin{2,28}
*/
std::string get_child(gsize index) const;
/** Gets the string vector of the Variant.
* @return The vector.
* @newin{2,28}
*/
std::vector<std::string> get() const;
// Object paths are merely strings so it is possible to get them already with
// the existing get() methods in this class.
/** Gets a VariantIter of the Variant.
* @return the VaraintIter.
* @newin{2,28}
*/
VariantIter get_iter() const;
};
/** Specialization of Variant containing a dictionary (a map of (key,
* value) elements).
* @newin{2,28}
* @ingroup Variant
*/
template<class K, class V>
class Variant< std::map<K, V> >: public VariantContainerBase
{
public:
using CppType = std::pair<K, V>;
using CppContainerType = std::map<K, V>;
/// Default constructor.
Variant< std::map<K, V> >()
: VariantContainerBase()
{}
/** GVariant constructor.
* @param castitem The GVariant to wrap.
* @param take_a_reference Whether to take an extra reference of the
* GVariant or not (not taking one could destroy the GVariant with the
* wrapper).
*/
explicit Variant< std::map<K, V> >(GVariant* castitem,
bool take_a_reference = false)
: VariantContainerBase(castitem, take_a_reference)
{}
/** Gets the VariantType.
* @return The VariantType.
* @newin{2,28}
*/
static const VariantType& variant_type() G_GNUC_CONST;
/** Creates a new Variant containing a dictionary from a map.
* @param data The map to use for creation.
* @return The new Variant holding a dictionary.
* @newin{2,28}
*/
static Variant< std::map<K, V> > create(const std::map<K, V>& data);
/** Gets a specific dictionary entry from the string array. It is an error
* if @a index is greater than the number of child items in the container.
* See VariantContainerBase::get_n_children().
*
* This function is O(1).
*
* @param index The index of the element.
* @return The dictionary entry at index @a index.
* @throw std::out_of_range
* @newin{2,28}
*/
std::pair<K, V> get_child(gsize index) const;
/** Looks up a value in a dictionary Variant.
* @param key The key to look up.
* @param value A location in which to store the value if found.
* @return <tt>true</tt> if the key is found, <tt>false</tt> otherwise.
*/
bool lookup(const K& key, V& value) const;
/** Gets the map (the dictionary) of the Variant.
* @return The vector.
* @newin{2,28}
*/
std::map<K, V> get() const;
/** Gets a VariantIter of the Variant.
* @return the VaraintIter.
* @newin{2,28}
*/
VariantIter get_iter() const;
};
} // namespace Glib
//We ignore g_variant_get_*() methods that are wrapped by Variant<> specializations, such as in variant_basictypes.h.m4.
/* Include generated specializations of Variant<> for fundamental types:
*/
#define _GLIBMM_VARIANT_H_INCLUDE_VARIANT_BASICTYPES_H
#include <glibmm/variant_basictypes.h>
#undef _GLIBMM_VARIANT_H_INCLUDE_VARIANT_BASICTYPES_H
namespace Glib
{
/*--------------------Variant< Variant<T> >---------------------*/
template<class T>
Variant< Variant<T> >::Variant()
: VariantContainerBase()
{
}
template<class T>
Variant< Variant<T> >::Variant(GVariant* castitem, bool take_a_reference)
: VariantContainerBase(castitem, take_a_reference)
{
}
// static
template<class T>
const VariantType& Variant< Variant<T> >::variant_type()
{
return VARIANT_TYPE_VARIANT;
}
template<class T>
Variant< Variant<T> > Variant< Variant<T> >::create(const Variant<T>& data)
{
Variant< Variant<T> > result = Variant< Variant<T> >(
g_variant_new_variant(const_cast<GVariant*>(data.gobj())));
return result;
}
template<class T>
Variant<T> Variant< Variant<T> >::get() const
{
GVariant* const gvariant = g_variant_get_variant(gobject_);
return Variant<T>(gvariant);
}
/*--------------------Variant< std::pair<K, V> >---------------------*/
// static
template<class K, class V>
const VariantType& Variant< std::pair<K, V> >::variant_type()
{
static VariantType type(
g_variant_type_new_dict_entry(Variant<K>::variant_type().gobj(),
Variant<V>::variant_type().gobj()));
return type;
}
template<class K, class V>
Variant< std::pair<K, V> >
Variant< std::pair<K, V> >::create(const std::pair<K, V>& data)
{
Variant<K> key = Variant<K>::create(data.first);
Variant<V> value = Variant<V>::create(data.second);
Variant< std::pair<K, V> > result = Variant< std::pair<K, V> >(
g_variant_new_dict_entry(key.gobj(), value.gobj()));
return result;
}
template<class K, class V>
std::pair<K, V> Variant< std::pair<K, V> >::get() const
{
// Get the key (the first element of this VariantContainerBase).
Variant<K> key;
VariantContainerBase::get_child(key, 0);
// Get the value (the second element of this VariantContainerBase).
Variant<V> value;
VariantContainerBase::get_child(value, 1);
std::pair<K, V> result(key.get(), value.get());
return result;
}
/*---------------------Variant< std::vector<T> >---------------------*/
// static
template<class T>
const VariantType& Variant< std::vector<T> >::variant_type()
{
static VariantType type =
VariantType::create_array(Variant<T>::variant_type());
return type;
}
template<class T>
Variant< std::vector<T> >
Variant< std::vector<T> >::create(const std::vector<T>& data)
{
// Get the variant type of the array.
VariantType array_variant_type = Variant< std::vector<T> >::variant_type();
// Create a GVariantBuilder to build the array.
GVariantBuilder* builder = g_variant_builder_new(array_variant_type.gobj());
// Add the elements of the vector into the builder.
for(const auto& element : data)
{
Glib::Variant<T> variant = Glib::Variant<T>::create(element);
g_variant_builder_add_value(builder, variant.gobj());
}
// Create the variant using the builder.
Variant< std::vector<T> > result =
Variant< std::vector<T> >(g_variant_new(
reinterpret_cast<const gchar*>(array_variant_type.gobj()), builder));
g_variant_builder_unref(builder);
return result;
}
template<class T>
T Variant< std::vector<T> >::get_child(gsize index) const
{
if(index >= g_variant_n_children(const_cast<GVariant*>(gobj())))
throw std::out_of_range(
"Variant< std::vector<T> >::get_child(): Index out of bounds.");
Glib::Variant<T> variant;
GVariant* gvariant =
g_variant_get_child_value(const_cast<GVariant*>(gobj()), index);
variant.init(gvariant);
return variant.get();
}
template<class T>
std::vector<T> Variant< std::vector<T> >::get() const
{
std::vector<T> result;
gsize n_children = g_variant_n_children(const_cast<GVariant*>(gobj()));
for(gsize i = 0; i < n_children; i++)
{
Glib::Variant<T> variant;
GVariant* gvariant =
g_variant_get_child_value(const_cast<GVariant*>(gobj()), i);
variant.init(gvariant);
result.emplace_back(variant.get());
}
return result;
}
template<class T>
VariantIter Variant< std::vector<T> >::get_iter() const
{
return VariantContainerBase::get_iter(variant_type());
}
/*---------------------Variant< std::map<K, V> > --------------------*/
// static
template<class K, class V>
const VariantType& Variant< std::map<K, V> >::variant_type()
{
static VariantType type =
VariantType::create_array(Variant< std::pair<K, V> >::variant_type());
return type;
}
template<class K, class V>
Variant< std::map<K, V> >
Variant< std::map<K, V> >::create(const std::map<K, V>& data)
{
// Get the variant type of the elements.
VariantType element_variant_type =
Variant< std::pair<K, V> >::variant_type();
// Get the variant type of the array.
VariantType array_variant_type = Variant< std::map<K, V> >::variant_type();
// Create a GVariantBuilder to build the array.
GVariantBuilder* builder = g_variant_builder_new(array_variant_type.gobj());
// Add the elements of the map into the builder.
for(const auto& element : data)
{
auto dict_entry =
Variant< std::pair<K, V> >::create(element);
g_variant_builder_add_value(builder, dict_entry.gobj());
}
// Create the variant using the builder.
Variant< std::map<K, V> > result = Variant< std::map<K, V> >(g_variant_new(
reinterpret_cast<const gchar*>(array_variant_type.gobj()), builder));
g_variant_builder_unref(builder);
return result;
}
template<class K, class V>
std::pair<K, V>
Variant< std::map<K, V> >::get_child(gsize index) const
{
Variant< std::pair<K, V> > dict_entry;
VariantContainerBase::get_child(dict_entry, index);
return dict_entry.get();
}
template<class K, class V>
bool Variant< std::map<K, V> >::lookup(const K& key, V& value) const
{
// The code in this method pretty much reflects the g_variant_lookup_value()
// function except that it's more general to deal with keys that are not
// just strings.
VariantIter iter = get_iter();
Variant< std::pair<K, V> > entry;
while(iter.next_value(entry))
{
std::pair<K, V> element = entry.get();
if(element.first == key)
{
value = element.second;
return true;
}
}
return false;
}
template<class K, class V>
std::map<K, V> Variant< std::map<K, V> >::get() const
{
std::map<K, V> result;
VariantIter iter = get_iter();
Variant< std::pair<K, V> > entry;
while(iter.next_value(entry))
{
result.insert(entry.get());
}
return result;
}
template<class K, class V>
VariantIter Variant< std::map<K, V> >::get_iter() const
{
return VariantContainerBase::get_iter(variant_type());
}
} // namespace Glib
namespace Glib
{
/** @relates Glib::VariantBase
* @param lhs The left-hand side
* @param rhs The right-hand side
*/
inline void swap(VariantBase& lhs, VariantBase& rhs) noexcept
{ lhs.swap(rhs); }
} // namespace Glib
namespace Glib
{
/** A Glib::wrap() method for this object.
*
* @param object The C instance.
* @param take_copy False if the result should take ownership of the C instance. True if it should take a new copy or ref.
* @result A C++ instance that wraps this C instance.
*
* @relates Glib::VariantBase
*/
Glib::VariantBase wrap(GVariant* object, bool take_copy = false);
} // namespace Glib
#endif /* _GLIBMM_VARIANT_H */
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