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servo/components/style/values/computed/mod.rs
Emilio Cobos Álvarez 6cfdd989d5 style: Implement <tabpanels> and <deck> without XUL layout 
Gijs for front-end bits, layout for the new CSS properties and the
removal of nsDeckFrame / nsStackLayout, Jamie and Morgan for the a11y
changes.

As discussed in the bug, the main tricky part here is handling a11y
correctly. For <deck>, that's trivial (just use `visibility: hidden` to
hide the panels visually, while removing the unselected panels from the
a11y tree).

For <tabpanels> however we need to do something special. We do want to
hide stuff visually, but we want to preserve the contents in the a11y
tree.

For that, the easiest fix is introducing a new privileged CSS property
(-moz-subtree-hidden-only-visually), which takes care of not painting
the frame, but marks stuff offscreen in the accessibility tree. This is
not intended to be a property used widely.

Other than that, the changes are relatively straight-forward, though
some of the accessible/mac changes I could get a sanity-check on.

Differential Revision: https://phabricator.services.mozilla.com/D157875
2023-11-03 08:59:49 +01:00

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/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at https://mozilla.org/MPL/2.0/. */
//! Computed values.
use self::transform::DirectionVector;
use super::animated::ToAnimatedValue;
use super::generics::grid::GridTemplateComponent as GenericGridTemplateComponent;
use super::generics::grid::ImplicitGridTracks as GenericImplicitGridTracks;
use super::generics::grid::{GenericGridLine, GenericTrackBreadth};
use super::generics::grid::{GenericTrackSize, TrackList as GenericTrackList};
use super::generics::transform::IsParallelTo;
use super::generics::{self, GreaterThanOrEqualToOne, NonNegative, ZeroToOne};
use super::specified;
use super::{CSSFloat, CSSInteger};
use crate::computed_value_flags::ComputedValueFlags;
use crate::context::QuirksMode;
use crate::stylesheets::container_rule::ContainerInfo;
use crate::font_metrics::{FontMetrics, FontMetricsOrientation};
use crate::media_queries::Device;
#[cfg(feature = "gecko")]
use crate::properties;
use crate::properties::{ComputedValues, LonghandId, StyleBuilder};
use crate::rule_cache::RuleCacheConditions;
use crate::values::specified::length::FontBaseSize;
use crate::{ArcSlice, Atom, One};
use euclid::{default, Point2D, Rect, Size2D};
use servo_arc::Arc;
use std::cell::RefCell;
use std::cmp;
use std::f32;
use std::ops::{Add, Sub};
#[cfg(feature = "gecko")]
pub use self::align::{
AlignContent, AlignItems, AlignTracks, JustifyContent, JustifyItems, JustifyTracks,
SelfAlignment,
};
#[cfg(feature = "gecko")]
pub use self::align::{AlignSelf, JustifySelf};
pub use self::angle::Angle;
pub use self::background::{BackgroundRepeat, BackgroundSize};
pub use self::basic_shape::FillRule;
pub use self::border::{BorderCornerRadius, BorderRadius, BorderSpacing};
pub use self::border::{BorderImageRepeat, BorderImageSideWidth};
pub use self::border::{BorderImageSlice, BorderImageWidth};
pub use self::box_::{AnimationIterationCount, AnimationName, AnimationTimeline, Contain, ContainerName, ContainerType};
pub use self::box_::{Appearance, BreakBetween, BreakWithin, Clear, ContentVisibility, ContainIntrinsicSize, Float};
pub use self::box_::{Display, LineClamp, Overflow, OverflowAnchor, TransitionProperty};
pub use self::box_::{OverflowClipBox, OverscrollBehavior, Perspective, Resize, ScrollbarGutter};
pub use self::box_::{ScrollAxis, ScrollSnapAlign, ScrollSnapAxis, ScrollSnapStop};
pub use self::box_::{ScrollSnapStrictness, ScrollSnapType, ScrollTimelineName};
pub use self::box_::{TouchAction, VerticalAlign, WillChange};
pub use self::color::{Color, ColorOrAuto, ColorPropertyValue, ColorScheme, PrintColorAdjust};
pub use self::column::ColumnCount;
pub use self::counters::{Content, ContentItem, CounterIncrement, CounterReset, CounterSet};
pub use self::easing::TimingFunction;
pub use self::effects::{BoxShadow, Filter, SimpleShadow};
pub use self::flex::FlexBasis;
pub use self::font::{FontFamily, FontLanguageOverride, FontStyle};
pub use self::font::{FontFeatureSettings, FontVariantLigatures, FontVariantNumeric};
pub use self::font::{FontSize, FontSizeAdjust, FontStretch, FontSynthesis};
pub use self::font::{FontVariantAlternates, FontWeight};
pub use self::font::{FontVariantEastAsian, FontVariationSettings};
pub use self::font::{MathDepth, MozScriptMinSize, MozScriptSizeMultiplier, XLang, XTextZoom};
pub use self::image::{Gradient, Image, ImageRendering, LineDirection, MozImageRect};
pub use self::length::{CSSPixelLength, NonNegativeLength};
pub use self::length::{Length, LengthOrNumber, LengthPercentage, NonNegativeLengthOrNumber};
pub use self::length::{LengthOrAuto, LengthPercentageOrAuto, MaxSize, Size};
pub use self::length::{NonNegativeLengthPercentage, NonNegativeLengthPercentageOrAuto};
#[cfg(feature = "gecko")]
pub use self::list::ListStyleType;
pub use self::list::Quotes;
pub use self::motion::{OffsetPath, OffsetRotate};
pub use self::outline::OutlineStyle;
pub use self::page::{PageOrientation, PageName, PageSize, PaperSize};
pub use self::percentage::{NonNegativePercentage, Percentage};
pub use self::position::AspectRatio;
pub use self::position::{
GridAutoFlow, GridTemplateAreas, MasonryAutoFlow, Position, PositionOrAuto, ZIndex,
};
pub use self::ratio::Ratio;
pub use self::rect::NonNegativeLengthOrNumberRect;
pub use self::resolution::Resolution;
pub use self::svg::{DProperty, MozContextProperties};
pub use self::svg::{SVGLength, SVGOpacity, SVGPaint, SVGPaintKind};
pub use self::svg::{SVGPaintOrder, SVGStrokeDashArray, SVGWidth};
pub use self::text::HyphenateCharacter;
pub use self::text::TextUnderlinePosition;
pub use self::text::{InitialLetter, LetterSpacing, LineBreak, LineHeight};
pub use self::text::{OverflowWrap, RubyPosition, TextOverflow, WordBreak, WordSpacing};
pub use self::text::{TextAlign, TextAlignLast, TextEmphasisPosition, TextEmphasisStyle};
pub use self::text::{TextDecorationLength, TextDecorationSkipInk, TextJustify};
pub use self::time::Time;
pub use self::transform::{Rotate, Scale, Transform, TransformOperation};
pub use self::transform::{TransformOrigin, TransformStyle, Translate};
#[cfg(feature = "gecko")]
pub use self::ui::CursorImage;
pub use self::ui::{Cursor, BoolInteger, UserSelect};
pub use super::specified::TextTransform;
pub use super::specified::ViewportVariant;
pub use super::specified::{BorderStyle, TextDecorationLine};
pub use app_units::Au;
#[cfg(feature = "gecko")]
pub mod align;
pub mod angle;
pub mod background;
pub mod basic_shape;
pub mod border;
#[path = "box.rs"]
pub mod box_;
pub mod color;
pub mod column;
pub mod counters;
pub mod easing;
pub mod effects;
pub mod flex;
pub mod font;
pub mod image;
pub mod length;
pub mod length_percentage;
pub mod list;
pub mod motion;
pub mod outline;
pub mod page;
pub mod percentage;
pub mod position;
pub mod ratio;
pub mod rect;
pub mod resolution;
pub mod svg;
pub mod table;
pub mod text;
pub mod time;
pub mod transform;
pub mod ui;
pub mod url;
/// A `Context` is all the data a specified value could ever need to compute
/// itself and be transformed to a computed value.
pub struct Context<'a> {
/// Values accessed through this need to be in the properties "computed
/// early": color, text-decoration, font-size, display, position, float,
/// border-*-style, outline-style, font-family, writing-mode...
pub builder: StyleBuilder<'a>,
/// A cached computed system font value, for use by gecko.
///
/// See properties/longhands/font.mako.rs
#[cfg(feature = "gecko")]
pub cached_system_font: Option<properties::longhands::system_font::ComputedSystemFont>,
/// A dummy option for servo so initializing a computed::Context isn't
/// painful.
///
/// TODO(emilio): Make constructors for Context, and drop this.
#[cfg(feature = "servo")]
pub cached_system_font: Option<()>,
/// Whether or not we are computing the media list in a media query
pub in_media_query: bool,
/// The quirks mode of this context.
pub quirks_mode: QuirksMode,
/// Whether this computation is being done for a SMIL animation.
///
/// This is used to allow certain properties to generate out-of-range
/// values, which SMIL allows.
pub for_smil_animation: bool,
/// Returns the container information to evaluate a given container query.
pub container_info: Option<ContainerInfo>,
/// The property we are computing a value for, if it is a non-inherited
/// property. None if we are computed a value for an inherited property
/// or not computing for a property at all (e.g. in a media query
/// evaluation).
pub for_non_inherited_property: Option<LonghandId>,
/// The conditions to cache a rule node on the rule cache.
///
/// FIXME(emilio): Drop the refcell.
pub rule_cache_conditions: RefCell<&'a mut RuleCacheConditions>,
}
impl<'a> Context<'a> {
/// Creates a suitable context for media query evaluation, in which
/// font-relative units compute against the system_font, and executes `f`
/// with it.
pub fn for_media_query_evaluation<F, R>(device: &Device, quirks_mode: QuirksMode, f: F) -> R
where
F: FnOnce(&Context) -> R,
{
let mut conditions = RuleCacheConditions::default();
let context = Context {
builder: StyleBuilder::for_inheritance(device, None, None),
cached_system_font: None,
in_media_query: true,
quirks_mode,
for_smil_animation: false,
container_info: None,
for_non_inherited_property: None,
rule_cache_conditions: RefCell::new(&mut conditions),
};
f(&context)
}
/// Creates a suitable context for container query evaluation for the style
/// specified.
pub fn for_container_query_evaluation<F, R>(
device: &Device,
container_info_and_style: Option<(ContainerInfo, Arc<ComputedValues>)>,
f: F,
) -> R
where
F: FnOnce(&Context) -> R,
{
let mut conditions = RuleCacheConditions::default();
let (container_info, style) = match container_info_and_style {
Some((ci, s)) => (Some(ci), Some(s)),
None => (None, None),
};
let style = style.as_ref().map(|s| &**s);
let quirks_mode = device.quirks_mode();
let context = Context {
builder: StyleBuilder::for_inheritance(device, style, None),
cached_system_font: None,
in_media_query: true,
quirks_mode,
for_smil_animation: false,
container_info,
for_non_inherited_property: None,
rule_cache_conditions: RefCell::new(&mut conditions),
};
f(&context)
}
/// The current device.
pub fn device(&self) -> &Device {
self.builder.device
}
/// Queries font metrics.
pub fn query_font_metrics(
&self,
base_size: FontBaseSize,
orientation: FontMetricsOrientation,
retrieve_math_scales: bool,
) -> FontMetrics {
if self.for_non_inherited_property.is_some() {
self.rule_cache_conditions.borrow_mut().set_uncacheable();
}
self.builder.add_flags(match base_size {
FontBaseSize::CurrentStyle => ComputedValueFlags::DEPENDS_ON_SELF_FONT_METRICS,
FontBaseSize::InheritedStyle => ComputedValueFlags::DEPENDS_ON_INHERITED_FONT_METRICS,
});
let size = base_size.resolve(self);
let style = self.style();
let (wm, font) = match base_size {
FontBaseSize::CurrentStyle => (style.writing_mode, style.get_font()),
// This is only used for font-size computation.
FontBaseSize::InheritedStyle => {
(*style.inherited_writing_mode(), style.get_parent_font())
},
};
let vertical = match orientation {
FontMetricsOrientation::MatchContextPreferHorizontal => {
wm.is_vertical() && wm.is_upright()
},
FontMetricsOrientation::MatchContextPreferVertical => {
wm.is_vertical() && !wm.is_sideways()
},
FontMetricsOrientation::Horizontal => false,
};
self.device().query_font_metrics(
vertical,
font,
size,
self.in_media_query,
retrieve_math_scales,
)
}
/// The current viewport size, used to resolve viewport units.
pub fn viewport_size_for_viewport_unit_resolution(
&self,
variant: ViewportVariant,
) -> default::Size2D<Au> {
self.builder
.device
.au_viewport_size_for_viewport_unit_resolution(variant)
}
/// The default computed style we're getting our reset style from.
pub fn default_style(&self) -> &ComputedValues {
self.builder.default_style()
}
/// The current style.
pub fn style(&self) -> &StyleBuilder {
&self.builder
}
/// Apply text-zoom if enabled.
#[cfg(feature = "gecko")]
pub fn maybe_zoom_text(&self, size: CSSPixelLength) -> CSSPixelLength {
// We disable zoom for <svg:text> by unsetting the
// -x-text-zoom property, which leads to a false value
// in mAllowZoomAndMinSize
if self.style().get_font().gecko.mAllowZoomAndMinSize {
self.device().zoom_text(size)
} else {
size
}
}
/// (Servo doesn't do text-zoom)
#[cfg(feature = "servo")]
pub fn maybe_zoom_text(&self, size: CSSPixelLength) -> CSSPixelLength {
size
}
}
/// An iterator over a slice of computed values
#[derive(Clone)]
pub struct ComputedVecIter<'a, 'cx, 'cx_a: 'cx, S: ToComputedValue + 'a> {
cx: &'cx Context<'cx_a>,
values: &'a [S],
}
impl<'a, 'cx, 'cx_a: 'cx, S: ToComputedValue + 'a> ComputedVecIter<'a, 'cx, 'cx_a, S> {
/// Construct an iterator from a slice of specified values and a context
pub fn new(cx: &'cx Context<'cx_a>, values: &'a [S]) -> Self {
ComputedVecIter {
cx,
values,
}
}
}
impl<'a, 'cx, 'cx_a: 'cx, S: ToComputedValue + 'a> ExactSizeIterator
for ComputedVecIter<'a, 'cx, 'cx_a, S>
{
fn len(&self) -> usize {
self.values.len()
}
}
impl<'a, 'cx, 'cx_a: 'cx, S: ToComputedValue + 'a> Iterator for ComputedVecIter<'a, 'cx, 'cx_a, S> {
type Item = S::ComputedValue;
fn next(&mut self) -> Option<Self::Item> {
if let Some((next, rest)) = self.values.split_first() {
let ret = next.to_computed_value(self.cx);
self.values = rest;
Some(ret)
} else {
None
}
}
fn size_hint(&self) -> (usize, Option<usize>) {
(self.values.len(), Some(self.values.len()))
}
}
/// A trait to represent the conversion between computed and specified values.
///
/// This trait is derivable with `#[derive(ToComputedValue)]`. The derived
/// implementation just calls `ToComputedValue::to_computed_value` on each field
/// of the passed value. The deriving code assumes that if the type isn't
/// generic, then the trait can be implemented as simple `Clone::clone` calls,
/// this means that a manual implementation with `ComputedValue = Self` is bogus
/// if it returns anything else than a clone.
pub trait ToComputedValue {
/// The computed value type we're going to be converted to.
type ComputedValue;
/// Convert a specified value to a computed value, using itself and the data
/// inside the `Context`.
fn to_computed_value(&self, context: &Context) -> Self::ComputedValue;
/// Convert a computed value to specified value form.
///
/// This will be used for recascading during animation.
/// Such from_computed_valued values should recompute to the same value.
fn from_computed_value(computed: &Self::ComputedValue) -> Self;
}
impl<A, B> ToComputedValue for (A, B)
where
A: ToComputedValue,
B: ToComputedValue,
{
type ComputedValue = (
<A as ToComputedValue>::ComputedValue,
<B as ToComputedValue>::ComputedValue,
);
#[inline]
fn to_computed_value(&self, context: &Context) -> Self::ComputedValue {
(
self.0.to_computed_value(context),
self.1.to_computed_value(context),
)
}
#[inline]
fn from_computed_value(computed: &Self::ComputedValue) -> Self {
(
A::from_computed_value(&computed.0),
B::from_computed_value(&computed.1),
)
}
}
impl<T> ToComputedValue for Option<T>
where
T: ToComputedValue,
{
type ComputedValue = Option<<T as ToComputedValue>::ComputedValue>;
#[inline]
fn to_computed_value(&self, context: &Context) -> Self::ComputedValue {
self.as_ref().map(|item| item.to_computed_value(context))
}
#[inline]
fn from_computed_value(computed: &Self::ComputedValue) -> Self {
computed.as_ref().map(T::from_computed_value)
}
}
impl<T> ToComputedValue for default::Size2D<T>
where
T: ToComputedValue,
{
type ComputedValue = default::Size2D<<T as ToComputedValue>::ComputedValue>;
#[inline]
fn to_computed_value(&self, context: &Context) -> Self::ComputedValue {
Size2D::new(
self.width.to_computed_value(context),
self.height.to_computed_value(context),
)
}
#[inline]
fn from_computed_value(computed: &Self::ComputedValue) -> Self {
Size2D::new(
T::from_computed_value(&computed.width),
T::from_computed_value(&computed.height),
)
}
}
impl<T> ToComputedValue for Vec<T>
where
T: ToComputedValue,
{
type ComputedValue = Vec<<T as ToComputedValue>::ComputedValue>;
#[inline]
fn to_computed_value(&self, context: &Context) -> Self::ComputedValue {
self.iter()
.map(|item| item.to_computed_value(context))
.collect()
}
#[inline]
fn from_computed_value(computed: &Self::ComputedValue) -> Self {
computed.iter().map(T::from_computed_value).collect()
}
}
impl<T> ToComputedValue for Box<T>
where
T: ToComputedValue,
{
type ComputedValue = Box<<T as ToComputedValue>::ComputedValue>;
#[inline]
fn to_computed_value(&self, context: &Context) -> Self::ComputedValue {
Box::new(T::to_computed_value(self, context))
}
#[inline]
fn from_computed_value(computed: &Self::ComputedValue) -> Self {
Box::new(T::from_computed_value(computed))
}
}
impl<T> ToComputedValue for Box<[T]>
where
T: ToComputedValue,
{
type ComputedValue = Box<[<T as ToComputedValue>::ComputedValue]>;
#[inline]
fn to_computed_value(&self, context: &Context) -> Self::ComputedValue {
self.iter()
.map(|item| item.to_computed_value(context))
.collect::<Vec<_>>()
.into_boxed_slice()
}
#[inline]
fn from_computed_value(computed: &Self::ComputedValue) -> Self {
computed
.iter()
.map(T::from_computed_value)
.collect::<Vec<_>>()
.into_boxed_slice()
}
}
impl<T> ToComputedValue for crate::OwnedSlice<T>
where
T: ToComputedValue,
{
type ComputedValue = crate::OwnedSlice<<T as ToComputedValue>::ComputedValue>;
#[inline]
fn to_computed_value(&self, context: &Context) -> Self::ComputedValue {
self.iter()
.map(|item| item.to_computed_value(context))
.collect()
}
#[inline]
fn from_computed_value(computed: &Self::ComputedValue) -> Self {
computed.iter().map(T::from_computed_value).collect()
}
}
// NOTE(emilio): This is implementable more generically, but it's unlikely
// what you want there, as it forces you to have an extra allocation.
//
// We could do that if needed, ideally with specialization for the case where
// ComputedValue = T. But we don't need it for now.
impl<T> ToComputedValue for Arc<T>
where
T: ToComputedValue<ComputedValue = T>,
{
type ComputedValue = Self;
#[inline]
fn to_computed_value(&self, _: &Context) -> Self {
self.clone()
}
#[inline]
fn from_computed_value(computed: &Self) -> Self {
computed.clone()
}
}
// Same caveat as above applies.
impl<T> ToComputedValue for ArcSlice<T>
where
T: ToComputedValue<ComputedValue = T>,
{
type ComputedValue = Self;
#[inline]
fn to_computed_value(&self, _: &Context) -> Self {
self.clone()
}
#[inline]
fn from_computed_value(computed: &Self) -> Self {
computed.clone()
}
}
trivial_to_computed_value!(());
trivial_to_computed_value!(bool);
trivial_to_computed_value!(f32);
trivial_to_computed_value!(i32);
trivial_to_computed_value!(u8);
trivial_to_computed_value!(u16);
trivial_to_computed_value!(u32);
trivial_to_computed_value!(usize);
trivial_to_computed_value!(Atom);
trivial_to_computed_value!(crate::values::AtomIdent);
#[cfg(feature = "servo")]
trivial_to_computed_value!(crate::Namespace);
#[cfg(feature = "servo")]
trivial_to_computed_value!(crate::Prefix);
trivial_to_computed_value!(String);
trivial_to_computed_value!(Box<str>);
trivial_to_computed_value!(crate::OwnedStr);
trivial_to_computed_value!(style_traits::values::specified::AllowedNumericType);
#[allow(missing_docs)]
#[derive(
Animate,
Clone,
ComputeSquaredDistance,
Copy,
Debug,
MallocSizeOf,
PartialEq,
ToAnimatedZero,
ToCss,
ToResolvedValue,
)]
#[repr(C, u8)]
pub enum AngleOrPercentage {
Percentage(Percentage),
Angle(Angle),
}
impl ToComputedValue for specified::AngleOrPercentage {
type ComputedValue = AngleOrPercentage;
#[inline]
fn to_computed_value(&self, context: &Context) -> AngleOrPercentage {
match *self {
specified::AngleOrPercentage::Percentage(percentage) => {
AngleOrPercentage::Percentage(percentage.to_computed_value(context))
},
specified::AngleOrPercentage::Angle(angle) => {
AngleOrPercentage::Angle(angle.to_computed_value(context))
},
}
}
#[inline]
fn from_computed_value(computed: &AngleOrPercentage) -> Self {
match *computed {
AngleOrPercentage::Percentage(percentage) => specified::AngleOrPercentage::Percentage(
ToComputedValue::from_computed_value(&percentage),
),
AngleOrPercentage::Angle(angle) => {
specified::AngleOrPercentage::Angle(ToComputedValue::from_computed_value(&angle))
},
}
}
}
/// A `<number>` value.
pub type Number = CSSFloat;
impl IsParallelTo for (Number, Number, Number) {
fn is_parallel_to(&self, vector: &DirectionVector) -> bool {
use euclid::approxeq::ApproxEq;
// If a and b is parallel, the angle between them is 0deg, so
// a x b = |a|*|b|*sin(0)*n = 0 * n, |a x b| == 0.
let self_vector = DirectionVector::new(self.0, self.1, self.2);
self_vector
.cross(*vector)
.square_length()
.approx_eq(&0.0f32)
}
}
/// A wrapper of Number, but the value >= 0.
pub type NonNegativeNumber = NonNegative<CSSFloat>;
impl ToAnimatedValue for NonNegativeNumber {
type AnimatedValue = CSSFloat;
#[inline]
fn to_animated_value(self) -> Self::AnimatedValue {
self.0
}
#[inline]
fn from_animated_value(animated: Self::AnimatedValue) -> Self {
animated.max(0.).into()
}
}
impl From<CSSFloat> for NonNegativeNumber {
#[inline]
fn from(number: CSSFloat) -> NonNegativeNumber {
NonNegative::<CSSFloat>(number)
}
}
impl From<NonNegativeNumber> for CSSFloat {
#[inline]
fn from(number: NonNegativeNumber) -> CSSFloat {
number.0
}
}
impl One for NonNegativeNumber {
#[inline]
fn one() -> Self {
NonNegative(1.0)
}
#[inline]
fn is_one(&self) -> bool {
self.0 == 1.0
}
}
/// A wrapper of Number, but the value between 0 and 1
pub type ZeroToOneNumber = ZeroToOne<CSSFloat>;
impl ToAnimatedValue for ZeroToOneNumber {
type AnimatedValue = CSSFloat;
#[inline]
fn to_animated_value(self) -> Self::AnimatedValue {
self.0
}
#[inline]
fn from_animated_value(animated: Self::AnimatedValue) -> Self {
Self(animated.max(0.).min(1.))
}
}
impl From<CSSFloat> for ZeroToOneNumber {
#[inline]
fn from(number: CSSFloat) -> Self {
Self(number)
}
}
/// A wrapper of Number, but the value >= 1.
pub type GreaterThanOrEqualToOneNumber = GreaterThanOrEqualToOne<CSSFloat>;
impl ToAnimatedValue for GreaterThanOrEqualToOneNumber {
type AnimatedValue = CSSFloat;
#[inline]
fn to_animated_value(self) -> Self::AnimatedValue {
self.0
}
#[inline]
fn from_animated_value(animated: Self::AnimatedValue) -> Self {
animated.max(1.).into()
}
}
impl From<CSSFloat> for GreaterThanOrEqualToOneNumber {
#[inline]
fn from(number: CSSFloat) -> GreaterThanOrEqualToOneNumber {
GreaterThanOrEqualToOne::<CSSFloat>(number)
}
}
impl From<GreaterThanOrEqualToOneNumber> for CSSFloat {
#[inline]
fn from(number: GreaterThanOrEqualToOneNumber) -> CSSFloat {
number.0
}
}
#[allow(missing_docs)]
#[derive(
Animate,
Clone,
ComputeSquaredDistance,
Copy,
Debug,
MallocSizeOf,
PartialEq,
ToAnimatedZero,
ToCss,
ToResolvedValue,
)]
#[repr(C, u8)]
pub enum NumberOrPercentage {
Percentage(Percentage),
Number(Number),
}
impl NumberOrPercentage {
fn clamp_to_non_negative(self) -> Self {
match self {
NumberOrPercentage::Percentage(p) => {
NumberOrPercentage::Percentage(p.clamp_to_non_negative())
},
NumberOrPercentage::Number(n) => NumberOrPercentage::Number(n.max(0.)),
}
}
}
impl ToComputedValue for specified::NumberOrPercentage {
type ComputedValue = NumberOrPercentage;
#[inline]
fn to_computed_value(&self, context: &Context) -> NumberOrPercentage {
match *self {
specified::NumberOrPercentage::Percentage(percentage) => {
NumberOrPercentage::Percentage(percentage.to_computed_value(context))
},
specified::NumberOrPercentage::Number(number) => {
NumberOrPercentage::Number(number.to_computed_value(context))
},
}
}
#[inline]
fn from_computed_value(computed: &NumberOrPercentage) -> Self {
match *computed {
NumberOrPercentage::Percentage(percentage) => {
specified::NumberOrPercentage::Percentage(ToComputedValue::from_computed_value(
&percentage,
))
},
NumberOrPercentage::Number(number) => {
specified::NumberOrPercentage::Number(ToComputedValue::from_computed_value(&number))
},
}
}
}
/// A non-negative <number-percentage>.
pub type NonNegativeNumberOrPercentage = NonNegative<NumberOrPercentage>;
impl NonNegativeNumberOrPercentage {
/// Returns the `100%` value.
#[inline]
pub fn hundred_percent() -> Self {
NonNegative(NumberOrPercentage::Percentage(Percentage::hundred()))
}
}
impl ToAnimatedValue for NonNegativeNumberOrPercentage {
type AnimatedValue = NumberOrPercentage;
#[inline]
fn to_animated_value(self) -> Self::AnimatedValue {
self.0
}
#[inline]
fn from_animated_value(animated: Self::AnimatedValue) -> Self {
NonNegative(animated.clamp_to_non_negative())
}
}
/// A type used for opacity.
pub type Opacity = CSSFloat;
/// A `<integer>` value.
pub type Integer = CSSInteger;
/// A wrapper of Integer, but only accept a value >= 1.
pub type PositiveInteger = GreaterThanOrEqualToOne<CSSInteger>;
impl ToAnimatedValue for PositiveInteger {
type AnimatedValue = CSSInteger;
#[inline]
fn to_animated_value(self) -> Self::AnimatedValue {
self.0
}
#[inline]
fn from_animated_value(animated: Self::AnimatedValue) -> Self {
cmp::max(animated, 1).into()
}
}
impl From<CSSInteger> for PositiveInteger {
#[inline]
fn from(int: CSSInteger) -> PositiveInteger {
GreaterThanOrEqualToOne::<CSSInteger>(int)
}
}
/// rect(...) | auto
pub type ClipRect = generics::GenericClipRect<LengthOrAuto>;
/// rect(...) | auto
pub type ClipRectOrAuto = generics::GenericClipRectOrAuto<ClipRect>;
/// The computed value of a grid `<track-breadth>`
pub type TrackBreadth = GenericTrackBreadth<LengthPercentage>;
/// The computed value of a grid `<track-size>`
pub type TrackSize = GenericTrackSize<LengthPercentage>;
/// The computed value of a grid `<track-size>+`
pub type ImplicitGridTracks = GenericImplicitGridTracks<TrackSize>;
/// The computed value of a grid `<track-list>`
/// (could also be `<auto-track-list>` or `<explicit-track-list>`)
pub type TrackList = GenericTrackList<LengthPercentage, Integer>;
/// The computed value of a `<grid-line>`.
pub type GridLine = GenericGridLine<Integer>;
/// `<grid-template-rows> | <grid-template-columns>`
pub type GridTemplateComponent = GenericGridTemplateComponent<LengthPercentage, Integer>;
impl ClipRect {
/// Given a border box, resolves the clip rect against the border box
/// in the same space the border box is in
pub fn for_border_rect<T: Copy + From<Length> + Add<Output = T> + Sub<Output = T>, U>(
&self,
border_box: Rect<T, U>,
) -> Rect<T, U> {
fn extract_clip_component<T: From<Length>>(p: &LengthOrAuto, or: T) -> T {
match *p {
LengthOrAuto::Auto => or,
LengthOrAuto::LengthPercentage(ref length) => T::from(*length),
}
}
let clip_origin = Point2D::new(
From::from(self.left.auto_is(|| Length::new(0.))),
From::from(self.top.auto_is(|| Length::new(0.))),
);
let right = extract_clip_component(&self.right, border_box.size.width);
let bottom = extract_clip_component(&self.bottom, border_box.size.height);
let clip_size = Size2D::new(right - clip_origin.x, bottom - clip_origin.y);
Rect::new(clip_origin, clip_size).translate(border_box.origin.to_vector())
}
}
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