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// Take a look at the license at the top of the repository in the LICENSE file.
use crate::Transform;
use glib::{translate::*, IntoGStr};
impl Transform {
/// Parses the given @string into a transform and puts it in
/// @out_transform.
///
/// Strings printed via [`to_str()`][Self::to_str()]
/// can be read in again successfully using this function.
///
/// If @string does not describe a valid transform, [`false`] is
/// returned and [`None`] is put in @out_transform.
/// ## `string`
/// the string to parse
///
/// # Returns
///
/// [`true`] if @string described a valid transform.
///
/// ## `out_transform`
/// The location to put the transform in
#[doc(alias = "gsk_transform_parse")]
pub fn parse(string: impl IntoGStr) -> Result<Self, glib::BoolError> {
assert_initialized_main_thread!();
unsafe {
string.run_with_gstr(|string| {
let mut out_transform = std::ptr::null_mut();
let ret = from_glib(ffi::gsk_transform_parse(
string.as_ptr(),
&mut out_transform,
));
if ret {
Ok(from_glib_full(out_transform))
} else {
Err(glib::bool_error!("Can't parse Transform"))
}
})
}
}
/// Inverts the given transform.
///
/// If @self is not invertible, [`None`] is returned.
/// Note that inverting [`None`] also returns [`None`], which is
/// the correct inverse of [`None`]. If you need to differentiate
/// between those cases, you should check @self is not [`None`]
/// before calling this function.
///
/// # Returns
///
/// The inverted transform
#[doc(alias = "gsk_transform_invert")]
pub fn invert(self) -> Result<Self, glib::BoolError> {
unsafe {
let matrix = self.to_matrix();
if matrix == graphene::Matrix::new_identity() {
return Ok(self);
}
let res: Option<Self> = from_glib_full(ffi::gsk_transform_invert(self.into_glib_ptr()));
res.ok_or_else(|| glib::bool_error!("Failed to invert the transform"))
}
}
/// Rotates @self @angle degrees in 2D - or in 3D-speak, around the Z axis.
/// The rotation happens around the origin point of (0, 0).
/// ## `angle`
/// the rotation angle, in degrees (clockwise)
///
/// # Returns
///
/// The new transform
#[doc(alias = "gsk_transform_rotate")]
#[must_use]
pub fn rotate(self, angle: f32) -> Self {
unsafe {
let res: Option<Self> =
from_glib_full(ffi::gsk_transform_rotate(self.into_glib_ptr(), angle));
res.unwrap_or_else(Self::new)
}
}
/// Rotates @self @angle degrees around @axis.
///
/// For a rotation in 2D space, use [`rotate()`][Self::rotate()]
/// ## `angle`
/// the rotation angle, in degrees (clockwise)
/// ## `axis`
/// The rotation axis
///
/// # Returns
///
/// The new transform
#[doc(alias = "gsk_transform_rotate_3d")]
#[must_use]
pub fn rotate_3d(self, angle: f32, axis: &graphene::Vec3) -> Self {
unsafe {
let res: Option<Self> = from_glib_full(ffi::gsk_transform_rotate_3d(
self.into_glib_ptr(),
angle,
axis.to_glib_none().0,
));
res.unwrap_or_else(Self::new)
}
}
/// Scales @self in 2-dimensional space by the given factors.
///
/// Use [`scale_3d()`][Self::scale_3d()] to scale in all 3 dimensions.
/// ## `factor_x`
/// scaling factor on the X axis
/// ## `factor_y`
/// scaling factor on the Y axis
///
/// # Returns
///
/// The new transform
#[doc(alias = "gsk_transform_scale")]
#[must_use]
pub fn scale(self, factor_x: f32, factor_y: f32) -> Self {
unsafe {
let res: Option<Self> = from_glib_full(ffi::gsk_transform_scale(
self.into_glib_ptr(),
factor_x,
factor_y,
));
res.unwrap_or_else(Self::new)
}
}
/// Scales @self by the given factors.
/// ## `factor_x`
/// scaling factor on the X axis
/// ## `factor_y`
/// scaling factor on the Y axis
/// ## `factor_z`
/// scaling factor on the Z axis
///
/// # Returns
///
/// The new transform
#[doc(alias = "gsk_transform_scale_3d")]
#[must_use]
pub fn scale_3d(self, factor_x: f32, factor_y: f32, factor_z: f32) -> Self {
unsafe {
let res: Option<Self> = from_glib_full(ffi::gsk_transform_scale_3d(
self.into_glib_ptr(),
factor_x,
factor_y,
factor_z,
));
res.unwrap_or_else(Self::new)
}
}
/// Applies a skew transform.
/// ## `skew_x`
/// skew factor, in degrees, on the X axis
/// ## `skew_y`
/// skew factor, in degrees, on the Y axis
///
/// # Returns
///
/// The new transform
#[cfg(feature = "v4_6")]
#[cfg_attr(docsrs, doc(cfg(feature = "v4_6")))]
#[doc(alias = "gsk_transform_skew")]
#[must_use]
pub fn skew(self, skew_x: f32, skew_y: f32) -> Self {
unsafe {
let res: Option<Self> = from_glib_full(ffi::gsk_transform_skew(
self.into_glib_ptr(),
skew_x,
skew_y,
));
res.unwrap_or_else(Self::new)
}
}
/// Applies all the operations from @other to @self.
/// ## `other`
/// Transform to apply
///
/// # Returns
///
/// The new transform
#[doc(alias = "gsk_transform_transform")]
#[must_use]
pub fn transform(self, other: Option<&Self>) -> Self {
unsafe {
let res: Option<Self> = from_glib_full(ffi::gsk_transform_transform(
self.into_glib_ptr(),
other.to_glib_none().0,
));
res.unwrap_or_else(Self::new)
}
}
/// Translates @self in 2-dimensional space by @point.
/// ## `point`
/// the point to translate the transform by
///
/// # Returns
///
/// The new transform
#[doc(alias = "gsk_transform_translate")]
#[must_use]
pub fn translate(self, point: &graphene::Point) -> Self {
unsafe {
let res: Option<Self> = from_glib_full(ffi::gsk_transform_translate(
self.into_glib_ptr(),
point.to_glib_none().0,
));
res.unwrap_or_else(Self::new)
}
}
/// Translates @self by @point.
/// ## `point`
/// the point to translate the transform by
///
/// # Returns
///
/// The new transform
#[doc(alias = "gsk_transform_translate_3d")]
#[must_use]
pub fn translate_3d(self, point: &graphene::Point3D) -> Self {
unsafe {
let res: Option<Self> = from_glib_full(ffi::gsk_transform_translate_3d(
self.into_glib_ptr(),
point.to_glib_none().0,
));
res.unwrap_or_else(Self::new)
}
}
}
impl std::str::FromStr for Transform {
type Err = glib::BoolError;
fn from_str(s: &str) -> Result<Self, Self::Err> {
skip_assert_initialized!();
Self::parse(s)
}
}
#[test]
fn invert_identity_is_identity() {
let transform = Transform::new();
let output = transform.clone().invert();
assert_eq!(output.unwrap(), transform);
}