/* * Copyright © 2019 Benjamin Otte * * 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, see . * * Authors: Benjamin Otte */ #include "config.h" #include "gtkexpression.h" #include "gtkprivate.h" #include /** * GtkExpression: (ref-func gtk_expression_ref) (unref-func gtk_expression_unref) (set-value-func gtk_value_set_expression) (get-value-func gtk_value_get_expression) * * `GtkExpression` provides a way to describe references to values. * * An important aspect of expressions is that the value can be obtained * from a source that is several steps away. For example, an expression * may describe ‘the value of property A of `object1`, which is itself the * value of a property of `object2`’. And `object1` may not even exist yet * at the time that the expression is created. This is contrast to `GObject` * property bindings, which can only create direct connections between * the properties of two objects that must both exist for the duration * of the binding. * * An expression needs to be "evaluated" to obtain the value that it currently * refers to. An evaluation always happens in the context of a current object * called `this` (it mirrors the behavior of object-oriented languages), * which may or may not influence the result of the evaluation. Use * [method@Gtk.Expression.evaluate] for evaluating an expression. * * Various methods for defining expressions exist, from simple constants via * [ctor@Gtk.ConstantExpression.new] to looking up properties in a `GObject` * (even recursively) via [ctor@Gtk.PropertyExpression.new] or providing * custom functions to transform and combine expressions via * [ctor@Gtk.ClosureExpression.new]. * * Here is an example of a complex expression: * * ```c * color_expr = gtk_property_expression_new (GTK_TYPE_LIST_ITEM, * NULL, "item"); * expression = gtk_property_expression_new (GTK_TYPE_COLOR, * color_expr, "name"); * ``` * * when evaluated with `this` being a `GtkListItem`, it will obtain the * "item" property from the `GtkListItem`, and then obtain the "name" property * from the resulting object (which is assumed to be of type `GTK_TYPE_COLOR`). * * A more concise way to describe this would be * * ``` * this->item->name * ``` * * The most likely place where you will encounter expressions is in the context * of list models and list widgets using them. For example, `GtkDropDown` is * evaluating a `GtkExpression` to obtain strings from the items in its model * that it can then use to match against the contents of its search entry. * `GtkStringFilter` is using a `GtkExpression` for similar reasons. * * By default, expressions are not paying attention to changes and evaluation is * just a snapshot of the current state at a given time. To get informed about * changes, an expression needs to be "watched" via a [struct@Gtk.ExpressionWatch], * which will cause a callback to be called whenever the value of the expression may * have changed; [method@Gtk.Expression.watch] starts watching an expression, and * [method@Gtk.ExpressionWatch.unwatch] stops. * * Watches can be created for automatically updating the property of an object, * similar to GObject's `GBinding` mechanism, by using [method@Gtk.Expression.bind]. * * ## GtkExpression in GObject properties * * In order to use a `GtkExpression` as a `GObject` property, you must use the * [id@gtk_param_spec_expression] when creating a `GParamSpec` to install in the * `GObject` class being defined; for instance: * * ```c * obj_props[PROP_EXPRESSION] = * gtk_param_spec_expression ("expression", * "Expression", * "The expression used by the widget", * G_PARAM_READWRITE | * G_PARAM_STATIC_STRINGS | * G_PARAM_EXPLICIT_NOTIFY); * ``` * * When implementing the `GObjectClass.set_property` and `GObjectClass.get_property` * virtual functions, you must use [id@gtk_value_get_expression], to retrieve the * stored `GtkExpression` from the `GValue` container, and [id@gtk_value_set_expression], * to store the `GtkExpression` into the `GValue`; for instance: * * ```c * // in set_property()... * case PROP_EXPRESSION: * foo_widget_set_expression (foo, gtk_value_get_expression (value)); * break; * * // in get_property()... * case PROP_EXPRESSION: * gtk_value_set_expression (value, foo->expression); * break; * ``` * * ## GtkExpression in .ui files * * `GtkBuilder` has support for creating expressions. The syntax here can be used where * a `GtkExpression` object is needed like in a `` tag for an expression * property, or in a `` tag to bind a property to an expression. * * To create an property expression, use the `` element. It can have a `type` * attribute to specify the object type, and a `name` attribute to specify the property * to look up. The content of `` can either be an element specfiying the expression * to use the object, or a string that specifies the name of the object to use. * * Example: * * ```xml * string_filter * ``` * * To create a constant expression, use the `` element. If the type attribute * is specified, the element content is interpreted as a value of that type. Otherwise, * it is assumed to be an object. For instance: * * ```xml * string_filter * Hello, world * ``` * * To create a closure expression, use the `` element. The `type` and `function` * attributes specify what function to use for the closure, the content of the element * contains the expressions for the parameters. For instance: * * ```xml * * File size: * myfile * * ``` */ typedef struct _GtkExpressionClass GtkExpressionClass; typedef struct _GtkExpressionSubWatch GtkExpressionSubWatch; typedef struct _GtkExpressionTypeInfo GtkExpressionTypeInfo; struct _GtkExpression { GTypeInstance parent_instance; gatomicrefcount ref_count; GType value_type; GtkExpression *owner; }; struct _GtkExpressionClass { GTypeClass parent_class; void (* finalize) (GtkExpression *expr); gboolean (* is_static) (GtkExpression *expr); gboolean (* evaluate) (GtkExpression *expr, gpointer this, GValue *value); gsize (* watch_size) (GtkExpression *expr); void (* watch) (GtkExpression *self, GtkExpressionSubWatch *watch, gpointer this_, GtkExpressionNotify notify, gpointer user_data); void (* unwatch) (GtkExpression *self, GtkExpressionSubWatch *watch); }; struct _GtkExpressionTypeInfo { gsize instance_size; void (* instance_init) (GtkExpression *expr); void (* finalize) (GtkExpression *expr); gboolean (* is_static) (GtkExpression *expr); gboolean (* evaluate) (GtkExpression *expr, gpointer this, GValue *value); gsize (* watch_size) (GtkExpression *expr); void (* watch) (GtkExpression *self, GtkExpressionSubWatch *watch, gpointer this_, GtkExpressionNotify notify, gpointer user_data); void (* unwatch) (GtkExpression *self, GtkExpressionSubWatch *watch); }; /** * GtkExpressionWatch: * * An opaque structure representing a watched `GtkExpression`. * * The contents of `GtkExpressionWatch` should only be accessed through the * provided API. */ struct _GtkExpressionWatch { GtkExpression *expression; GObject *this; GDestroyNotify user_destroy; GtkExpressionNotify notify; gpointer user_data; guchar sub[0]; }; G_DEFINE_BOXED_TYPE (GtkExpressionWatch, gtk_expression_watch, gtk_expression_watch_ref, gtk_expression_watch_unref) #define GTK_EXPRESSION_GET_CLASS(obj) (G_TYPE_INSTANCE_GET_CLASS ((obj), GTK_TYPE_EXPRESSION, GtkExpressionClass)) /*< private > * GTK_DEFINE_EXPRESSION_TYPE: * @TypeName: the type name, in camel case * @type_name: the type name, in snake case * @type_info: the address of the `GtkExpressionTypeInfo` for the expression type * * Registers a new `GtkExpression` subclass with the given @TypeName and @type_info. * * Similarly to %G_DEFINE_TYPE, this macro will generate a `get_type()` * function that registers the event type. * * You can specify code to be run after the type registration; the `GType` of * the event is available in the `gtk_define_expression_type_id` variable. */ #define GTK_DEFINE_EXPRESSION_TYPE(TypeName, type_name, type_info) \ GType \ type_name ## _get_type (void) \ { \ static gsize gtk_define_expression_type_id__volatile; \ if (g_once_init_enter (>k_define_expression_type_id__volatile)) \ { \ GType gtk_define_expression_type_id = \ gtk_expression_type_register_static (g_intern_static_string (#TypeName), type_info); \ g_once_init_leave (>k_define_expression_type_id__volatile, gtk_define_expression_type_id); \ } \ return gtk_define_expression_type_id__volatile; \ } #define GTK_EXPRESSION_SUPER(expr) \ ((GtkExpressionClass *) g_type_class_peek (g_type_parent (G_TYPE_FROM_INSTANCE (expr)))) /* {{{ GtkExpression internals */ static void value_expression_init (GValue *value) { value->data[0].v_pointer = NULL; } static void value_expression_free_value (GValue *value) { if (value->data[0].v_pointer != NULL) gtk_expression_unref (value->data[0].v_pointer); } static void value_expression_copy_value (const GValue *src, GValue *dst) { if (src->data[0].v_pointer != NULL) dst->data[0].v_pointer = gtk_expression_ref (src->data[0].v_pointer); else dst->data[0].v_pointer = NULL; } static gpointer value_expression_peek_pointer (const GValue *value) { return value->data[0].v_pointer; } static char * value_expression_collect_value (GValue *value, guint n_collect_values, GTypeCValue *collect_values, guint collect_flags) { GtkExpression *expression = collect_values[0].v_pointer; if (expression == NULL) { value->data[0].v_pointer = NULL; return NULL; } if (expression->parent_instance.g_class == NULL) return g_strconcat ("invalid unclassed GtkExpression pointer for " "value type '", G_VALUE_TYPE_NAME (value), "'", NULL); value->data[0].v_pointer = gtk_expression_ref (expression); return NULL; } static char * value_expression_lcopy_value (const GValue *value, guint n_collect_values, GTypeCValue *collect_values, guint collect_flags) { GtkExpression **expression_p = collect_values[0].v_pointer; if (expression_p == NULL) return g_strconcat ("value location for '", G_VALUE_TYPE_NAME (value), "' passed as NULL", NULL); if (value->data[0].v_pointer == NULL) *expression_p = NULL; else if (collect_flags & G_VALUE_NOCOPY_CONTENTS) *expression_p = value->data[0].v_pointer; else *expression_p = gtk_expression_ref (value->data[0].v_pointer); return NULL; } /** * gtk_value_set_expression: * @value: a `GValue` initialized with type `GTK_TYPE_EXPRESSION` * @expression: a `GtkExpression` * * Stores the given `GtkExpression` inside `value`. * * The `GValue` will acquire a reference to the `expression`. */ void gtk_value_set_expression (GValue *value, GtkExpression *expression) { g_return_if_fail (G_VALUE_HOLDS (value, GTK_TYPE_EXPRESSION)); GtkExpression *old_expression = value->data[0].v_pointer; if (expression != NULL) { g_return_if_fail (GTK_IS_EXPRESSION (expression)); value->data[0].v_pointer = gtk_expression_ref (expression); } else { value->data[0].v_pointer = NULL; } if (old_expression != NULL) gtk_expression_unref (old_expression); } /** * gtk_value_take_expression: * @value: a `GValue` initialized with type `GTK_TYPE_EXPRESSION` * @expression: (transfer full) (nullable): a `GtkExpression` * * Stores the given `GtkExpression` inside `value`. * * This function transfers the ownership of the `expression` to the `GValue`. */ void gtk_value_take_expression (GValue *value, GtkExpression *expression) { g_return_if_fail (G_VALUE_HOLDS (value, GTK_TYPE_EXPRESSION)); GtkExpression *old_expression = value->data[0].v_pointer; if (expression != NULL) { g_return_if_fail (GTK_IS_EXPRESSION (expression)); value->data[0].v_pointer = expression; } else { value->data[0].v_pointer = NULL; } if (old_expression != NULL) gtk_expression_unref (old_expression); } /** * gtk_value_get_expression: * @value: a `GValue` initialized with type `GTK_TYPE_EXPRESSION` * * Retrieves the `GtkExpression` stored inside the given `value`. * * Returns: (transfer none) (nullable): a `GtkExpression` */ GtkExpression * gtk_value_get_expression (const GValue *value) { g_return_val_if_fail (G_VALUE_HOLDS (value, GTK_TYPE_EXPRESSION), NULL); return value->data[0].v_pointer; } /** * gtk_value_dup_expression: * @value: a `GValue` initialized with type `GTK_TYPE_EXPRESSION` * * Retrieves the `GtkExpression` stored inside the given `value`, and acquires * a reference to it. * * Returns: (transfer full) (nullable): a `GtkExpression` */ GtkExpression * gtk_value_dup_expression (const GValue *value) { g_return_val_if_fail (G_VALUE_HOLDS (value, GTK_TYPE_EXPRESSION), NULL); if (value->data[0].v_pointer == NULL) return NULL; GtkExpression *expression = value->data[0].v_pointer; return gtk_expression_ref (expression); } static void param_expression_init (GParamSpec *pspec) { } static void param_expression_set_default (GParamSpec *pspec, GValue *value) { value->data[0].v_pointer = NULL; } static gboolean param_expression_validate (GParamSpec *pspec, GValue *value) { GtkParamSpecExpression *espec = GTK_PARAM_SPEC_EXPRESSION (pspec); GtkExpression *expr = value->data[0].v_pointer; guint changed = 0; if (expr != NULL && !g_value_type_compatible (G_TYPE_FROM_INSTANCE (expr), G_PARAM_SPEC_VALUE_TYPE (espec))) { gtk_expression_unref (expr); value->data[0].v_pointer = NULL; changed++; } return changed; } static int param_expression_values_cmp (GParamSpec *pspec, const GValue *value1, const GValue *value2) { guint8 *p1 = value1->data[0].v_pointer; guint8 *p2 = value2->data[0].v_pointer; return p1 < p2 ? -1 : p1 > p2; } GType gtk_param_expression_get_type (void) { static gsize param_expression_type__volatile; if (g_once_init_enter (¶m_expression_type__volatile)) { const GParamSpecTypeInfo pspec_info = { sizeof (GtkParamSpecExpression), 16, param_expression_init, GTK_TYPE_EXPRESSION, NULL, param_expression_set_default, param_expression_validate, param_expression_values_cmp, }; GType param_expression_type = g_param_type_register_static (g_intern_static_string ("GtkParamSpecExpression"), &pspec_info); g_once_init_leave (¶m_expression_type__volatile, param_expression_type); } return param_expression_type__volatile; } /** * gtk_param_spec_expression: * @name: canonical name of the property * @nick: a user-readable name for the property * @blurb: a user-readable description of the property * @flags: flags for the property * * Creates a new `GParamSpec` instance for a property holding a `GtkExpression`. * * See `g_param_spec_internal()` for details on the property strings. * * Returns: (transfer full): a newly created property specification */ GParamSpec * gtk_param_spec_expression (const char *name, const char *nick, const char *blurb, GParamFlags flags) { GParamSpec *pspec = g_param_spec_internal (GTK_TYPE_PARAM_SPEC_EXPRESSION, name, nick, blurb, flags); pspec->value_type = GTK_TYPE_EXPRESSION; return pspec; } /* }}} */ /* {{{ GtkExpression internals */ static void gtk_expression_real_finalize (GtkExpression *self) { g_type_free_instance ((GTypeInstance *) self); } static gsize gtk_expression_real_watch_size (GtkExpression *self) { return 0; } static void gtk_expression_real_watch (GtkExpression *self, GtkExpressionSubWatch *watch, gpointer this_, GtkExpressionNotify notify, gpointer user_data) { } static void gtk_expression_real_unwatch (GtkExpression *self, GtkExpressionSubWatch *watch) { } static gsize gtk_expression_watch_size (GtkExpression *self) { return GTK_EXPRESSION_GET_CLASS (self)->watch_size (self); } static void gtk_expression_class_init (GtkExpressionClass *klass) { klass->finalize = gtk_expression_real_finalize; klass->watch_size = gtk_expression_real_watch_size; klass->watch = gtk_expression_real_watch; klass->unwatch = gtk_expression_real_unwatch; } static void gtk_expression_init (GtkExpression *self) { g_atomic_ref_count_init (&self->ref_count); } GType gtk_expression_get_type (void) { static gsize expression_type__volatile; if (g_once_init_enter (&expression_type__volatile)) { static const GTypeFundamentalInfo finfo = { (G_TYPE_FLAG_CLASSED | G_TYPE_FLAG_INSTANTIATABLE | G_TYPE_FLAG_DERIVABLE | G_TYPE_FLAG_DEEP_DERIVABLE), }; static const GTypeValueTable value_table = { value_expression_init, value_expression_free_value, value_expression_copy_value, value_expression_peek_pointer, "p", value_expression_collect_value, "p", value_expression_lcopy_value, }; const GTypeInfo event_info = { /* Class */ sizeof (GtkExpressionClass), (GBaseInitFunc) NULL, (GBaseFinalizeFunc) NULL, (GClassInitFunc) gtk_expression_class_init, (GClassFinalizeFunc) NULL, NULL, /* Instance */ sizeof (GtkExpression), 0, (GInstanceInitFunc) gtk_expression_init, /* GValue */ &value_table, }; GType expression_type = g_type_register_fundamental (g_type_fundamental_next (), g_intern_static_string ("GtkExpression"), &event_info, &finfo, G_TYPE_FLAG_ABSTRACT); g_once_init_leave (&expression_type__volatile, expression_type); } return expression_type__volatile; } static void gtk_expression_generic_class_init (gpointer g_class, gpointer class_data) { GtkExpressionTypeInfo *info = class_data; GtkExpressionClass *expression_class = g_class; /* Mandatory */ expression_class->is_static = info->is_static; expression_class->evaluate = info->evaluate; /* Optional */ if (info->finalize != NULL) expression_class->finalize = info->finalize; if (info->watch_size != NULL) expression_class->watch_size = info->watch_size; if (info->watch != NULL) expression_class->watch = info->watch; if (info->unwatch != NULL) expression_class->unwatch = info->unwatch; g_free (info); } static GType gtk_expression_type_register_static (const char *type_name, const GtkExpressionTypeInfo *type_info) { GTypeInfo info; info.class_size = sizeof (GtkExpressionClass); info.base_init = NULL; info.base_finalize = NULL; info.class_init = gtk_expression_generic_class_init; info.class_finalize = NULL; info.class_data = g_memdup2 (type_info, sizeof (GtkExpressionTypeInfo)); info.instance_size = type_info->instance_size; info.n_preallocs = 0; info.instance_init = (GInstanceInitFunc) type_info->instance_init; info.value_table = NULL; return g_type_register_static (GTK_TYPE_EXPRESSION, type_name, &info, 0); } /*< private > * gtk_expression_alloc: * @expression_type: the type of expression to create * @value_type: the type of the value returned by this expression * * Returns: (transfer full): the newly created `GtkExpression` */ static gpointer gtk_expression_alloc (GType expression_type, GType value_type) { GtkExpression *self; self = (GtkExpression *) g_type_create_instance (expression_type); self->value_type = value_type; return self; } static void gtk_expression_subwatch_init (GtkExpression *self, GtkExpressionSubWatch *watch, gpointer this, GtkExpressionNotify notify, gpointer user_data) { GTK_EXPRESSION_GET_CLASS (self)->watch (self, watch, this, notify, user_data); } static void gtk_expression_subwatch_finish (GtkExpression *self, GtkExpressionSubWatch *watch) { GTK_EXPRESSION_GET_CLASS (self)->unwatch (self, watch); } /* }}} */ /* {{{ GtkConstantExpression */ /** * GtkConstantExpression: * * A constant value in a `GtkExpression`. */ struct _GtkConstantExpression { GtkExpression parent; GValue value; }; static void gtk_constant_expression_finalize (GtkExpression *expr) { GtkConstantExpression *self = (GtkConstantExpression *) expr; g_value_unset (&self->value); GTK_EXPRESSION_SUPER (expr)->finalize (expr); } static gboolean gtk_constant_expression_is_static (GtkExpression *expr) { return TRUE; } static gboolean gtk_constant_expression_evaluate (GtkExpression *expr, gpointer this, GValue *value) { GtkConstantExpression *self = (GtkConstantExpression *) expr; g_value_init (value, G_VALUE_TYPE (&self->value)); g_value_copy (&self->value, value); return TRUE; } static const GtkExpressionTypeInfo gtk_constant_expression_info = { sizeof (GtkConstantExpression), NULL, gtk_constant_expression_finalize, gtk_constant_expression_is_static, gtk_constant_expression_evaluate, NULL, NULL, NULL, }; GTK_DEFINE_EXPRESSION_TYPE (GtkConstantExpression, gtk_constant_expression, >k_constant_expression_info) /** * gtk_constant_expression_new: * @value_type: The type of the object * @...: arguments to create the object from * * Creates a `GtkExpression` that evaluates to the * object given by the arguments. * * Returns: (transfer full) (type GtkConstantExpression): a new `GtkExpression` */ GtkExpression * gtk_constant_expression_new (GType value_type, ...) { GValue value = G_VALUE_INIT; GtkExpression *result; va_list args; char *error; va_start (args, value_type); G_VALUE_COLLECT_INIT (&value, value_type, args, G_VALUE_NOCOPY_CONTENTS, &error); if (error) { g_critical ("%s: %s", G_STRLOC, error); g_free (error); /* we purposely leak the value here, it might not be * in a sane state if an error condition occurred */ return NULL; } result = gtk_constant_expression_new_for_value (&value); g_value_unset (&value); va_end (args); return result; } /** * gtk_constant_expression_new_for_value: (constructor) * @value: a `GValue` * * Creates an expression that always evaluates to the given `value`. * * Returns: (transfer full) (type GtkConstantExpression): a new `GtkExpression` **/ GtkExpression * gtk_constant_expression_new_for_value (const GValue *value) { GtkExpression *result; GtkConstantExpression *self; g_return_val_if_fail (G_IS_VALUE (value), NULL); result = gtk_expression_alloc (GTK_TYPE_CONSTANT_EXPRESSION, G_VALUE_TYPE (value)); self = (GtkConstantExpression *) result; g_value_init (&self->value, G_VALUE_TYPE (value)); g_value_copy (value, &self->value); return result; } /** * gtk_constant_expression_get_value: * @expression: (type GtkConstantExpression): a constant `GtkExpression` * * Gets the value that a constant expression evaluates to. * * Returns: (transfer none): the value */ const GValue * gtk_constant_expression_get_value (GtkExpression *expression) { GtkConstantExpression *self = (GtkConstantExpression *) expression; g_return_val_if_fail (G_TYPE_CHECK_INSTANCE_TYPE (expression, GTK_TYPE_CONSTANT_EXPRESSION), NULL); return &self->value; } /* }}} */ /* {{{ GtkObjectExpression */ typedef struct _GtkObjectExpressionWatch GtkObjectExpressionWatch; /** * GtkObjectExpression: * * A `GObject` value in a `GtkExpression`. */ struct _GtkObjectExpression { GtkExpression parent; GObject *object; GSList *watches; }; struct _GtkObjectExpressionWatch { GtkExpressionNotify notify; gpointer user_data; }; static void gtk_object_expression_weak_ref_cb (gpointer data, GObject *object) { GtkObjectExpression *self = (GtkObjectExpression *) data; GSList *l; self->object = NULL; for (l = self->watches; l; l = l->next) { GtkObjectExpressionWatch *owatch = l->data; owatch->notify (owatch->user_data); } } static void gtk_object_expression_finalize (GtkExpression *expr) { GtkObjectExpression *self = (GtkObjectExpression *) expr; if (self->object) g_object_weak_unref (self->object, gtk_object_expression_weak_ref_cb, self); g_assert (self->watches == NULL); GTK_EXPRESSION_SUPER (expr)->finalize (expr); } static gboolean gtk_object_expression_is_static (GtkExpression *expr) { return FALSE; } static gboolean gtk_object_expression_evaluate (GtkExpression *expr, gpointer this, GValue *value) { GtkObjectExpression *self = (GtkObjectExpression *) expr; if (self->object == NULL) return FALSE; g_value_init (value, gtk_expression_get_value_type (expr)); g_value_set_object (value, self->object); return TRUE; } static gsize gtk_object_expression_watch_size (GtkExpression *expr) { return sizeof (GtkObjectExpressionWatch); } static void gtk_object_expression_watch (GtkExpression *expr, GtkExpressionSubWatch *watch, gpointer this_, GtkExpressionNotify notify, gpointer user_data) { GtkObjectExpression *self = (GtkObjectExpression *) expr; GtkObjectExpressionWatch *owatch = (GtkObjectExpressionWatch *) watch; owatch->notify = notify; owatch->user_data = user_data; self->watches = g_slist_prepend (self->watches, owatch); } static void gtk_object_expression_unwatch (GtkExpression *expr, GtkExpressionSubWatch *watch) { GtkObjectExpression *self = (GtkObjectExpression *) expr; self->watches = g_slist_remove (self->watches, watch); } static const GtkExpressionTypeInfo gtk_object_expression_info = { sizeof (GtkObjectExpression), NULL, gtk_object_expression_finalize, gtk_object_expression_is_static, gtk_object_expression_evaluate, gtk_object_expression_watch_size, gtk_object_expression_watch, gtk_object_expression_unwatch }; GTK_DEFINE_EXPRESSION_TYPE (GtkObjectExpression, gtk_object_expression, >k_object_expression_info) /** * gtk_object_expression_new: (constructor) * @object: (transfer none): object to watch * * Creates an expression evaluating to the given `object` with a weak reference. * * Once the `object` is disposed, it will fail to evaluate. * * This expression is meant to break reference cycles. * * If you want to keep a reference to `object`, use [ctor@Gtk.ConstantExpression.new]. * * Returns: (type GtkObjectExpression) (transfer full): a new `GtkExpression` **/ GtkExpression * gtk_object_expression_new (GObject *object) { GtkExpression *result; GtkObjectExpression *self; g_return_val_if_fail (G_IS_OBJECT (object), NULL); result = gtk_expression_alloc (GTK_TYPE_OBJECT_EXPRESSION, G_OBJECT_TYPE (object)); self = (GtkObjectExpression *) result; self->object = object; g_object_weak_ref (object, gtk_object_expression_weak_ref_cb, self); return result; } /** * gtk_object_expression_get_object: * @expression: (type GtkObjectExpression): an object `GtkExpression` * * Gets the object that the expression evaluates to. * * Returns: (transfer none) (nullable): the object, or `NULL` */ GObject * gtk_object_expression_get_object (GtkExpression *expression) { GtkObjectExpression *self = (GtkObjectExpression *) expression; g_return_val_if_fail (G_TYPE_CHECK_INSTANCE_TYPE (expression, GTK_TYPE_OBJECT_EXPRESSION), NULL); return self->object; } /* }}} */ /* {{{ GtkPropertyExpression */ /** * GtkPropertyExpression: * * A `GObject` property value in a `GtkExpression`. */ struct _GtkPropertyExpression { GtkExpression parent; GtkExpression *expr; GParamSpec *pspec; }; static void gtk_property_expression_finalize (GtkExpression *expr) { GtkPropertyExpression *self = (GtkPropertyExpression *) expr; g_clear_pointer (&self->expr, gtk_expression_unref); GTK_EXPRESSION_SUPER (expr)->finalize (expr); } static gboolean gtk_property_expression_is_static (GtkExpression *expr) { return FALSE; } static GObject * gtk_property_expression_get_object (GtkPropertyExpression *self, gpointer this) { GValue expr_value = G_VALUE_INIT; GObject *object; if (self->expr == NULL) { if (this) return g_object_ref (this); else return NULL; } if (!gtk_expression_evaluate (self->expr, this, &expr_value)) return NULL; if (!G_VALUE_HOLDS_OBJECT (&expr_value)) { g_value_unset (&expr_value); return NULL; } object = g_value_dup_object (&expr_value); g_value_unset (&expr_value); if (object == NULL) return NULL; if (!G_TYPE_CHECK_INSTANCE_TYPE (object, self->pspec->owner_type)) { g_object_unref (object); return NULL; } return object; } static gboolean gtk_property_expression_evaluate (GtkExpression *expr, gpointer this, GValue *value) { GtkPropertyExpression *self = (GtkPropertyExpression *) expr; GObject *object; object = gtk_property_expression_get_object (self, this); if (object == NULL) return FALSE; g_object_get_property (object, self->pspec->name, value); g_object_unref (object); return TRUE; } typedef struct _GtkPropertyExpressionWatch GtkPropertyExpressionWatch; struct _GtkPropertyExpressionWatch { GtkExpressionNotify notify; gpointer user_data; GtkPropertyExpression *expr; gpointer this; GClosure *closure; guchar sub[0]; }; static void gtk_property_expression_watch_destroy_closure (GtkPropertyExpressionWatch *pwatch) { if (pwatch->closure == NULL) return; g_closure_invalidate (pwatch->closure); g_closure_unref (pwatch->closure); pwatch->closure = NULL; } static void gtk_property_expression_watch_notify_cb (GObject *object, GParamSpec *pspec, GtkPropertyExpressionWatch *pwatch) { pwatch->notify (pwatch->user_data); } static void gtk_property_expression_watch_create_closure (GtkPropertyExpressionWatch *pwatch) { GObject *object; object = gtk_property_expression_get_object (pwatch->expr, pwatch->this); if (object == NULL) return; pwatch->closure = g_cclosure_new (G_CALLBACK (gtk_property_expression_watch_notify_cb), pwatch, NULL); if (!g_signal_connect_closure_by_id (object, g_signal_lookup ("notify", G_OBJECT_TYPE (object)), g_quark_from_string (pwatch->expr->pspec->name), g_closure_ref (pwatch->closure), FALSE)) { g_assert_not_reached (); } g_object_unref (object); } static void gtk_property_expression_watch_expr_notify_cb (gpointer data) { GtkPropertyExpressionWatch *pwatch = data; gtk_property_expression_watch_destroy_closure (pwatch); gtk_property_expression_watch_create_closure (pwatch); pwatch->notify (pwatch->user_data); } static gsize gtk_property_expression_watch_size (GtkExpression *expr) { GtkPropertyExpression *self = (GtkPropertyExpression *) expr; gsize result; result = sizeof (GtkPropertyExpressionWatch); if (self->expr) result += gtk_expression_watch_size (self->expr); return result; } static void gtk_property_expression_watch (GtkExpression *expr, GtkExpressionSubWatch *watch, gpointer this_, GtkExpressionNotify notify, gpointer user_data) { GtkPropertyExpressionWatch *pwatch = (GtkPropertyExpressionWatch *) watch; GtkPropertyExpression *self = (GtkPropertyExpression *) expr; pwatch->notify = notify; pwatch->user_data = user_data; pwatch->expr = self; pwatch->this = this_; if (self->expr && !gtk_expression_is_static (self->expr)) { gtk_expression_subwatch_init (self->expr, (GtkExpressionSubWatch *) pwatch->sub, this_, gtk_property_expression_watch_expr_notify_cb, pwatch); } gtk_property_expression_watch_create_closure (pwatch); } static void gtk_property_expression_unwatch (GtkExpression *expr, GtkExpressionSubWatch *watch) { GtkPropertyExpressionWatch *pwatch = (GtkPropertyExpressionWatch *) watch; GtkPropertyExpression *self = (GtkPropertyExpression *) expr; gtk_property_expression_watch_destroy_closure (pwatch); if (self->expr && !gtk_expression_is_static (self->expr)) gtk_expression_subwatch_finish (self->expr, (GtkExpressionSubWatch *) pwatch->sub); } static const GtkExpressionTypeInfo gtk_property_expression_info = { sizeof (GtkPropertyExpression), NULL, gtk_property_expression_finalize, gtk_property_expression_is_static, gtk_property_expression_evaluate, gtk_property_expression_watch_size, gtk_property_expression_watch, gtk_property_expression_unwatch }; GTK_DEFINE_EXPRESSION_TYPE (GtkPropertyExpression, gtk_property_expression, >k_property_expression_info) /** * gtk_property_expression_new: (constructor) * @this_type: The type to expect for the this type * @expression: (nullable) (transfer full): Expression to * evaluate to get the object to query or `NULL` to * query the `this` object * @property_name: name of the property * * Creates an expression that looks up a property. * * The object to use is found by evaluating the `expression`, * or using the `this` argument when `expression` is `NULL`. * * If the resulting object conforms to `this_type`, its property named * `property_name` will be queried. Otherwise, this expression's * evaluation will fail. * * The given `this_type` must have a property with `property_name`. * * Returns: (type GtkPropertyExpression) (transfer full): a new `GtkExpression` **/ GtkExpression * gtk_property_expression_new (GType this_type, GtkExpression *expression, const char *property_name) { GParamSpec *pspec; if (g_type_fundamental (this_type) == G_TYPE_OBJECT) { GObjectClass *class = g_type_class_ref (this_type); pspec = g_object_class_find_property (class, property_name); g_type_class_unref (class); } else if (g_type_fundamental (this_type) == G_TYPE_INTERFACE) { GTypeInterface *iface = g_type_default_interface_ref (this_type); pspec = g_object_interface_find_property (iface, property_name); g_type_default_interface_unref (iface); } else { g_critical ("Type `%s` does not support properties", g_type_name (this_type)); return NULL; } if (pspec == NULL) { g_critical ("Type `%s` does not have a property named `%s`", g_type_name (this_type), property_name); return NULL; } return gtk_property_expression_new_for_pspec (expression, pspec); } /** * gtk_property_expression_new_for_pspec: (constructor) * @expression: (nullable) (transfer full): Expression to * evaluate to get the object to query or `NULL` to * query the `this` object * @pspec: the `GParamSpec` for the property to query * * Creates an expression that looks up a property. * * The object to use is found by evaluating the `expression`, * or using the `this` argument when `expression` is `NULL`. * * If the resulting object conforms to `this_type`, its * property specified by `pspec` will be queried. * Otherwise, this expression's evaluation will fail. * * Returns: (type GtkPropertyExpression) (transfer full): a new `GtkExpression` **/ GtkExpression * gtk_property_expression_new_for_pspec (GtkExpression *expression, GParamSpec *pspec) { GtkExpression *result; GtkPropertyExpression *self; result = gtk_expression_alloc (GTK_TYPE_PROPERTY_EXPRESSION, pspec->value_type); self = (GtkPropertyExpression *) result; self->pspec = pspec; self->expr = expression; return result; } /** * gtk_property_expression_get_expression: * @expression: (type GtkPropertyExpression): a property `GtkExpression` * * Gets the expression specifying the object of * a property expression. * * Returns: (transfer none): the object expression */ GtkExpression * gtk_property_expression_get_expression (GtkExpression *expression) { GtkPropertyExpression *self = (GtkPropertyExpression *) expression; g_return_val_if_fail (G_TYPE_CHECK_INSTANCE_TYPE (expression, GTK_TYPE_PROPERTY_EXPRESSION), NULL); return self->expr; } /** * gtk_property_expression_get_pspec: * @expression: (type GtkPropertyExpression): a property `GtkExpression` * * Gets the `GParamSpec` specifying the property of * a property expression. * * Returns: (transfer none): the `GParamSpec` for the property */ GParamSpec * gtk_property_expression_get_pspec (GtkExpression *expression) { GtkPropertyExpression *self = (GtkPropertyExpression *) expression; g_return_val_if_fail (G_TYPE_CHECK_INSTANCE_TYPE (expression, GTK_TYPE_PROPERTY_EXPRESSION), NULL); return self->pspec; } /* }}} */ /* {{{ GtkClosureExpression */ /** * GtkClosureExpression: * * An expression using a custom `GClosure` to compute the value from * its parameters. */ struct _GtkClosureExpression { GtkExpression parent; GClosure *closure; guint n_params; GtkExpression **params; }; static void gtk_closure_expression_finalize (GtkExpression *expr) { GtkClosureExpression *self = (GtkClosureExpression *) expr; guint i; for (i = 0; i < self->n_params; i++) { gtk_expression_unref (self->params[i]); } g_free (self->params); g_closure_unref (self->closure); GTK_EXPRESSION_SUPER (expr)->finalize (expr); } static gboolean gtk_closure_expression_is_static (GtkExpression *expr) { GtkClosureExpression *self = (GtkClosureExpression *) expr; guint i; for (i = 0; i < self->n_params; i++) { if (!gtk_expression_is_static (self->params[i])) return FALSE; } return TRUE; } static gboolean gtk_closure_expression_evaluate (GtkExpression *expr, gpointer this, GValue *value) { GtkClosureExpression *self = (GtkClosureExpression *) expr; GValue *instance_and_params; gboolean result = TRUE; guint i; instance_and_params = g_alloca (sizeof (GValue) * (self->n_params + 1)); memset (instance_and_params, 0, sizeof (GValue) * (self->n_params + 1)); for (i = 0; i < self->n_params; i++) { if (!gtk_expression_evaluate (self->params[i], this, &instance_and_params[i + 1])) { result = FALSE; goto out; } } if (this) g_value_init_from_instance (instance_and_params, this); else g_value_init (instance_and_params, G_TYPE_OBJECT); g_value_init (value, expr->value_type); g_closure_invoke (self->closure, value, self->n_params + 1, instance_and_params, NULL); out: for (i = 0; i < self->n_params + 1; i++) g_value_unset (&instance_and_params[i]); return result; } typedef struct _GtkClosureExpressionWatch GtkClosureExpressionWatch; struct _GtkClosureExpressionWatch { GtkExpressionNotify notify; gpointer user_data; guchar sub[0]; }; static void gtk_closure_expression_watch_notify_cb (gpointer data) { GtkClosureExpressionWatch *cwatch = data; cwatch->notify (cwatch->user_data); } static gsize gtk_closure_expression_watch_size (GtkExpression *expr) { GtkClosureExpression *self = (GtkClosureExpression *) expr; gsize size; guint i; size = sizeof (GtkClosureExpressionWatch); for (i = 0; i < self->n_params; i++) { if (gtk_expression_is_static (self->params[i])) continue; size += gtk_expression_watch_size (self->params[i]); } return size; } static void gtk_closure_expression_watch (GtkExpression *expr, GtkExpressionSubWatch *watch, gpointer this_, GtkExpressionNotify notify, gpointer user_data) { GtkClosureExpressionWatch *cwatch = (GtkClosureExpressionWatch *) watch; GtkClosureExpression *self = (GtkClosureExpression *) expr; guchar *sub; guint i; cwatch->notify = notify; cwatch->user_data = user_data; sub = cwatch->sub; for (i = 0; i < self->n_params; i++) { if (gtk_expression_is_static (self->params[i])) continue; gtk_expression_subwatch_init (self->params[i], (GtkExpressionSubWatch *) sub, this_, gtk_closure_expression_watch_notify_cb, watch); sub += gtk_expression_watch_size (self->params[i]); } } static void gtk_closure_expression_unwatch (GtkExpression *expr, GtkExpressionSubWatch *watch) { GtkClosureExpressionWatch *cwatch = (GtkClosureExpressionWatch *) watch; GtkClosureExpression *self = (GtkClosureExpression *) expr; guchar *sub; guint i; sub = cwatch->sub; for (i = 0; i < self->n_params; i++) { if (gtk_expression_is_static (self->params[i])) continue; gtk_expression_subwatch_finish (self->params[i], (GtkExpressionSubWatch *) sub); sub += gtk_expression_watch_size (self->params[i]); } } static const GtkExpressionTypeInfo gtk_closure_expression_info = { sizeof (GtkClosureExpression), NULL, gtk_closure_expression_finalize, gtk_closure_expression_is_static, gtk_closure_expression_evaluate, gtk_closure_expression_watch_size, gtk_closure_expression_watch, gtk_closure_expression_unwatch }; GTK_DEFINE_EXPRESSION_TYPE (GtkClosureExpression, gtk_closure_expression, >k_closure_expression_info) /** * gtk_closure_expression_new: (constructor) * @value_type: the type of the value that this expression evaluates to * @closure: closure to call when evaluating this expression. If closure is floating, it is adopted * @n_params: the number of params needed for evaluating `closure` * @params: (nullable) (array length=n_params) (transfer full): expressions for each parameter * * Creates a `GtkExpression` that calls `closure` when it is evaluated. * * `closure` is called with the `this` object and the results of evaluating * the `params` expressions. * * Returns: (transfer full) (type GtkClosureExpression): a new `GtkExpression` */ GtkExpression * gtk_closure_expression_new (GType value_type, GClosure *closure, guint n_params, GtkExpression **params) { GtkExpression *result; GtkClosureExpression *self; guint i; g_return_val_if_fail (closure != NULL, NULL); g_return_val_if_fail (n_params == 0 || params != NULL, NULL); result = gtk_expression_alloc (GTK_TYPE_CLOSURE_EXPRESSION, value_type); self = (GtkClosureExpression *) result; self->closure = g_closure_ref (closure); g_closure_sink (closure); if (G_CLOSURE_NEEDS_MARSHAL (closure)) g_closure_set_marshal (closure, g_cclosure_marshal_generic); self->n_params = n_params; self->params = g_new (GtkExpression *, n_params); for (i = 0; i < n_params; i++) self->params[i] = params[i]; return result; } /* }}} */ /* {{{ GtkCClosureExpression */ /** * GtkCClosureExpression: * * A variant of `GtkClosureExpression` using a C closure. */ struct _GtkCClosureExpression { GtkClosureExpression parent; }; static const GtkExpressionTypeInfo gtk_cclosure_expression_info = { sizeof (GtkClosureExpression), NULL, gtk_closure_expression_finalize, gtk_closure_expression_is_static, gtk_closure_expression_evaluate, gtk_closure_expression_watch_size, gtk_closure_expression_watch, gtk_closure_expression_unwatch }; GTK_DEFINE_EXPRESSION_TYPE (GtkCClosureExpression, gtk_cclosure_expression, >k_cclosure_expression_info) /** * gtk_cclosure_expression_new: (constructor) * @value_type: the type of the value that this expression evaluates to * @marshal: (scope call) (nullable): marshaller used for creating a closure * @n_params: the number of params needed for evaluating @closure * @params: (array length=n_params) (transfer full): expressions for each parameter * @callback_func: (scope notified) (closure user_data) (destroy user_destroy): callback used for creating a closure * @user_data: (nullable): user data used for creating a closure * @user_destroy: (nullable): destroy notify for @user_data * * Creates a `GtkExpression` that calls `callback_func` when it is evaluated. * * This function is a variant of [ctor@Gtk.ClosureExpression.new] that * creates a `GClosure` by calling g_cclosure_new() with the given * `callback_func`, `user_data` and `user_destroy`. * * Returns: (transfer full) (type GtkCClosureExpression): a new `GtkExpression` */ GtkExpression * gtk_cclosure_expression_new (GType value_type, GClosureMarshal marshal, guint n_params, GtkExpression **params, GCallback callback_func, gpointer user_data, GClosureNotify user_destroy) { GtkExpression *result; GtkClosureExpression *self; GClosure *closure; guint i; g_return_val_if_fail (callback_func != NULL, NULL); g_return_val_if_fail (n_params == 0 || params != NULL, NULL); result = gtk_expression_alloc (GTK_TYPE_CCLOSURE_EXPRESSION, value_type); self = (GtkClosureExpression *) result; closure = g_cclosure_new (callback_func, user_data, user_destroy); if (marshal) g_closure_set_marshal (closure, marshal); self->closure = g_closure_ref (closure); g_closure_sink (closure); if (G_CLOSURE_NEEDS_MARSHAL (closure)) g_closure_set_marshal (closure, g_cclosure_marshal_generic); self->n_params = n_params; self->params = g_new (GtkExpression *, n_params); for (i = 0; i < n_params; i++) self->params[i] = params[i]; return result; } /* }}} */ /* {{{ GtkExpression public API */ /** * gtk_expression_ref: * @self: a `GtkExpression` * * Acquires a reference on the given `GtkExpression`. * * Returns: (transfer full): the `GtkExpression` with an additional reference */ GtkExpression * gtk_expression_ref (GtkExpression *self) { g_return_val_if_fail (GTK_IS_EXPRESSION (self), NULL); g_atomic_ref_count_inc (&self->ref_count); return self; } /** * gtk_expression_unref: * @self: (transfer full): a `GtkExpression` * * Releases a reference on the given `GtkExpression`. * * If the reference was the last, the resources associated to the `self` are * freed. */ void gtk_expression_unref (GtkExpression *self) { g_return_if_fail (GTK_IS_EXPRESSION (self)); if (g_atomic_ref_count_dec (&self->ref_count)) GTK_EXPRESSION_GET_CLASS (self)->finalize (self); } /** * gtk_expression_get_value_type: * @self: a `GtkExpression` * * Gets the `GType` that this expression evaluates to. * * This type is constant and will not change over the lifetime * of this expression. * * Returns: The type returned from [method@Gtk.Expression.evaluate] */ GType gtk_expression_get_value_type (GtkExpression *self) { g_return_val_if_fail (GTK_IS_EXPRESSION (self), G_TYPE_INVALID); return self->value_type; } /** * gtk_expression_evaluate: * @self: a `GtkExpression` * @this_: (transfer none) (type GObject) (nullable): the this argument for the evaluation * @value: an empty `GValue` * * Evaluates the given expression and on success stores the result * in @value. * * The `GType` of `value` will be the type given by * [method@Gtk.Expression.get_value_type]. * * It is possible that expressions cannot be evaluated - for example * when the expression references objects that have been destroyed or * set to `NULL`. In that case `value` will remain empty and `FALSE` * will be returned. * * Returns: `TRUE` if the expression could be evaluated **/ gboolean gtk_expression_evaluate (GtkExpression *self, gpointer this_, GValue *value) { g_return_val_if_fail (GTK_IS_EXPRESSION (self), FALSE); g_return_val_if_fail (this_ == NULL || G_IS_OBJECT (this_), FALSE); g_return_val_if_fail (value != NULL, FALSE); return GTK_EXPRESSION_GET_CLASS (self)->evaluate (self, this_, value); } /** * gtk_expression_is_static: * @self: a `GtkExpression` * * Checks if the expression is static. * * A static expression will never change its result when * [method@Gtk.Expression.evaluate] is called on it with the same arguments. * * That means a call to [method@Gtk.Expression.watch] is not necessary because * it will never trigger a notify. * * Returns: `TRUE` if the expression is static **/ gboolean gtk_expression_is_static (GtkExpression *self) { g_return_val_if_fail (GTK_IS_EXPRESSION (self), FALSE); return GTK_EXPRESSION_GET_CLASS (self)->is_static (self); } static gboolean gtk_expression_watch_is_watching (GtkExpressionWatch *watch) { return watch->expression != NULL; } static void gtk_expression_watch_this_cb (gpointer data, GObject *this) { GtkExpressionWatch *watch = data; watch->this = NULL; watch->notify (watch->user_data); gtk_expression_watch_unwatch (watch); } static void gtk_expression_watch_cb (gpointer data) { GtkExpressionWatch *watch = data; if (!gtk_expression_watch_is_watching (watch)) return; watch->notify (watch->user_data); } /** * gtk_expression_watch: * @self: a `GtkExpression` * @this_: (transfer none) (type GObject) (nullable): the `this` argument to * watch * @notify: (closure user_data): callback to invoke when the expression changes * @user_data: user data to pass to the `notify` callback * @user_destroy: destroy notify for `user_data` * * Watch the given `expression` for changes. * * The @notify function will be called whenever the evaluation of `self` * may have changed. * * GTK cannot guarantee that the evaluation did indeed change when the @notify * gets invoked, but it guarantees the opposite: When it did in fact change, * the @notify will be invoked. * * Returns: (transfer none): The newly installed watch. Note that the only * reference held to the watch will be released when the watch is unwatched * which can happen automatically, and not just via * [method@Gtk.ExpressionWatch.unwatch]. You should call [method@Gtk.ExpressionWatch.ref] * if you want to keep the watch around. **/ GtkExpressionWatch * gtk_expression_watch (GtkExpression *self, gpointer this_, GtkExpressionNotify notify, gpointer user_data, GDestroyNotify user_destroy) { GtkExpressionWatch *watch; g_return_val_if_fail (self != NULL, NULL); g_return_val_if_fail (this_ == NULL || G_IS_OBJECT (this_), NULL); g_return_val_if_fail (notify != NULL, NULL); watch = g_atomic_rc_box_alloc0 (sizeof (GtkExpressionWatch) + gtk_expression_watch_size (self)); watch->expression = gtk_expression_ref (self); watch->this = this_; if (this_) g_object_weak_ref (this_, gtk_expression_watch_this_cb, watch); watch->notify = notify; watch->user_data = user_data; watch->user_destroy = user_destroy; gtk_expression_subwatch_init (self, (GtkExpressionSubWatch *) watch->sub, this_, gtk_expression_watch_cb, watch); return watch; } /** * gtk_expression_watch_ref: * @watch: a `GtkExpressionWatch` * * Acquires a reference on the given `GtkExpressionWatch`. * * Returns: (transfer full): the `GtkExpressionWatch` with an additional reference */ GtkExpressionWatch * gtk_expression_watch_ref (GtkExpressionWatch *watch) { return g_atomic_rc_box_acquire (watch); } static void gtk_expression_watch_finalize (gpointer data) { GtkExpressionWatch *watch G_GNUC_UNUSED = data; g_assert (!gtk_expression_watch_is_watching (data)); } /** * gtk_expression_watch_unref: * @watch: (transfer full): a `GtkExpressionWatch` * * Releases a reference on the given `GtkExpressionWatch`. * * If the reference was the last, the resources associated to `self` are * freed. */ void gtk_expression_watch_unref (GtkExpressionWatch *watch) { g_atomic_rc_box_release_full (watch, gtk_expression_watch_finalize); } /** * gtk_expression_watch_unwatch: * @watch: (transfer none): watch to release * * Stops watching an expression. * * See [method@Gtk.Expression.watch] for how the watch * was established. */ void gtk_expression_watch_unwatch (GtkExpressionWatch *watch) { if (!gtk_expression_watch_is_watching (watch)) return; gtk_expression_subwatch_finish (watch->expression, (GtkExpressionSubWatch *) watch->sub); if (watch->this) g_object_weak_unref (watch->this, gtk_expression_watch_this_cb, watch); if (watch->user_destroy) watch->user_destroy (watch->user_data); g_clear_pointer (&watch->expression, gtk_expression_unref); gtk_expression_watch_unref (watch); } /** * gtk_expression_watch_evaluate: * @watch: a `GtkExpressionWatch` * @value: an empty `GValue` to be set * * Evaluates the watched expression and on success stores the result * in `value`. * * This is equivalent to calling [method@Gtk.Expression.evaluate] with the * expression and this pointer originally used to create `watch`. * * Returns: `TRUE` if the expression could be evaluated and `value` was set **/ gboolean gtk_expression_watch_evaluate (GtkExpressionWatch *watch, GValue *value) { g_return_val_if_fail (watch != NULL, FALSE); if (!gtk_expression_watch_is_watching (watch)) return FALSE; return gtk_expression_evaluate (watch->expression, watch->this, value); } typedef struct { GtkExpressionWatch *watch; GObject *target; GParamSpec *pspec; } GtkExpressionBind; static void invalidate_binds (gpointer unused, GObject *object) { GSList *l, *binds; binds = g_object_get_data (object, "gtk-expression-binds"); for (l = binds; l; l = l->next) { GtkExpressionBind *bind = l->data; /* This guarantees we neither try to update bindings * (which would wreck havoc because the object is * dispose()ing itself) nor try to destroy bindings * anymore, so destruction can be done in free_binds(). */ bind->target = NULL; } } static void free_binds (gpointer data) { GSList *l; for (l = data; l; l = l->next) { GtkExpressionBind *bind = l->data; g_assert (bind->target == NULL); if (bind->watch) gtk_expression_watch_unwatch (bind->watch); g_slice_free (GtkExpressionBind, bind); } g_slist_free (data); } static void gtk_expression_bind_free (gpointer data) { GtkExpressionBind *bind = data; if (bind->target) { GSList *binds; binds = g_object_steal_data (bind->target, "gtk-expression-binds"); binds = g_slist_remove (binds, bind); if (binds) g_object_set_data_full (bind->target, "gtk-expression-binds", binds, free_binds); else g_object_weak_unref (bind->target, invalidate_binds, NULL); g_slice_free (GtkExpressionBind, bind); } else { /* If a bind gets unwatched after invalidate_binds() but * before free_binds(), we end up here. This can happen if * the bind was watching itself or if the target's dispose() * function freed the object that was watched. * We make sure we don't destroy the binding or free_binds() will do * bad stuff, but we clear the watch, so free_binds() won't try to * unwatch() it. */ bind->watch = NULL; } } static void gtk_expression_bind_notify (gpointer data) { GValue value = G_VALUE_INIT; GtkExpressionBind *bind = data; if (bind->target == NULL) return; if (!gtk_expression_watch_evaluate (bind->watch, &value)) return; g_object_set_property (bind->target, bind->pspec->name, &value); g_value_unset (&value); } /** * gtk_expression_bind: * @self: (transfer full): a `GtkExpression` * @target: (transfer none) (type GObject): the target object to bind to * @property: name of the property on `target` to bind to * @this_: (transfer none) (type GObject) (nullable): the this argument for * the evaluation of `self` * * Bind `target`'s property named `property` to `self`. * * The value that `self` evaluates to is set via `g_object_set()` on * `target`. This is repeated whenever `self` changes to ensure that * the object's property stays synchronized with `self`. * * If `self`'s evaluation fails, `target`'s `property` is not updated. * You can ensure that this doesn't happen by using a fallback * expression. * * Note that this function takes ownership of `self`. If you want * to keep it around, you should [method@Gtk.Expression.ref] it beforehand. * * Returns: (transfer none): a `GtkExpressionWatch` **/ GtkExpressionWatch * gtk_expression_bind (GtkExpression *self, gpointer target, const char *property, gpointer this_) { GtkExpressionBind *bind; GParamSpec *pspec; GSList *binds; g_return_val_if_fail (GTK_IS_EXPRESSION (self), NULL); g_return_val_if_fail (G_IS_OBJECT (target), NULL); g_return_val_if_fail (property != NULL, NULL); g_return_val_if_fail (this_ == NULL || G_IS_OBJECT (this_), NULL); pspec = g_object_class_find_property (G_OBJECT_GET_CLASS (target), property); if (G_UNLIKELY (pspec == NULL)) { g_critical ("%s: Class '%s' has no property named '%s'", G_STRFUNC, G_OBJECT_TYPE_NAME (target), property); return NULL; } if (G_UNLIKELY ((pspec->flags & (G_PARAM_WRITABLE | G_PARAM_CONSTRUCT_ONLY)) != G_PARAM_WRITABLE)) { g_critical ("%s: property '%s' of class '%s' is not writable", G_STRFUNC, pspec->name, G_OBJECT_TYPE_NAME (target)); return NULL; } bind = g_slice_new0 (GtkExpressionBind); binds = g_object_steal_data (target, "gtk-expression-binds"); if (binds == NULL) g_object_weak_ref (target, invalidate_binds, NULL); bind->target = target; bind->pspec = pspec; bind->watch = gtk_expression_watch (self, this_, gtk_expression_bind_notify, bind, gtk_expression_bind_free); binds = g_slist_prepend (binds, bind); g_object_set_data_full (target, "gtk-expression-binds", binds, free_binds); gtk_expression_unref (self); gtk_expression_bind_notify (bind); return bind->watch; } /* }}} */