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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/. */
//! Specified values.
//!
//! TODO(emilio): Enhance docs.
use super::computed::transform::DirectionVector;
use super::computed::{Context, ToComputedValue};
use super::generics::grid::ImplicitGridTracks as GenericImplicitGridTracks;
use super::generics::grid::{GridLine as GenericGridLine, TrackBreadth as GenericTrackBreadth};
use super::generics::grid::{TrackList as GenericTrackList, TrackSize as GenericTrackSize};
use super::generics::transform::IsParallelTo;
use super::generics::{self, GreaterThanOrEqualToOne, NonNegative};
use super::{CSSFloat, CSSInteger};
use crate::context::QuirksMode;
use crate::parser::{Parse, ParserContext};
use crate::values::specified::calc::CalcNode;
use crate::values::{serialize_atom_identifier, serialize_number, AtomString};
use crate::{Atom, Namespace, One, Prefix, Zero};
use cssparser::{Parser, Token};
use std::fmt::{self, Write};
use std::ops::Add;
use style_traits::values::specified::AllowedNumericType;
use style_traits::{CssWriter, ParseError, SpecifiedValueInfo, StyleParseErrorKind, ToCss};
pub use self::align::{AlignContent, AlignItems, AlignSelf, ContentDistribution};
pub use self::align::{JustifyContent, JustifyItems, JustifySelf, SelfAlignment};
pub use self::angle::{AllowUnitlessZeroAngle, Angle};
pub use self::animation::{
AnimationComposition, AnimationDirection, AnimationDuration, AnimationFillMode,
AnimationIterationCount, AnimationName, AnimationPlayState, AnimationTimeline, ScrollAxis,
TimelineName, TransitionBehavior, TransitionProperty, ViewTimelineInset, ViewTransitionName,
};
pub use self::background::{BackgroundRepeat, BackgroundSize};
pub use self::basic_shape::FillRule;
pub use self::border::{
BorderCornerRadius, BorderImageRepeat, BorderImageSideWidth, BorderImageSlice,
BorderImageWidth, BorderRadius, BorderSideWidth, BorderSpacing, BorderStyle, LineWidth,
};
pub use self::box_::{
Appearance, BaselineSource, BreakBetween, BreakWithin, Clear, Contain, ContainIntrinsicSize,
ContainerName, ContainerType, ContentVisibility, Display, Float, LineClamp, Overflow,
OverflowAnchor, OverflowClipBox, OverscrollBehavior, Perspective, Resize, ScrollSnapAlign,
ScrollSnapAxis, ScrollSnapStop, ScrollSnapStrictness, ScrollSnapType, ScrollbarGutter,
TouchAction, VerticalAlign, WillChange, Zoom,
};
pub use self::color::{
Color, ColorOrAuto, ColorPropertyValue, ColorScheme, ForcedColorAdjust, 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, FontPalette, FontStyle};
pub use self::font::{FontFeatureSettings, FontVariantLigatures, FontVariantNumeric};
pub use self::font::{
FontSize, FontSizeAdjust, FontSizeAdjustFactor, FontSizeKeyword, FontStretch, FontSynthesis,
};
pub use self::font::{FontVariantAlternates, FontWeight};
pub use self::font::{FontVariantEastAsian, FontVariationSettings, LineHeight};
pub use self::font::{MathDepth, MozScriptMinSize, MozScriptSizeMultiplier, XLang, XTextScale};
pub use self::image::{EndingShape as GradientEndingShape, Gradient, Image, ImageRendering};
pub use self::length::{AbsoluteLength, AnchorSizeFunction, CalcLengthPercentage, CharacterWidth};
pub use self::length::{FontRelativeLength, Length, LengthOrNumber, NonNegativeLengthOrNumber};
pub use self::length::{LengthOrAuto, LengthPercentage, LengthPercentageOrAuto};
pub use self::length::{Margin, MaxSize, Size};
pub use self::length::{NoCalcLength, ViewportPercentageLength, ViewportVariant};
pub use self::length::{
NonNegativeLength, NonNegativeLengthPercentage, NonNegativeLengthPercentageOrAuto,
};
#[cfg(feature = "gecko")]
pub use self::list::ListStyleType;
pub use self::list::Quotes;
pub use self::motion::{OffsetPath, OffsetPosition, OffsetRotate};
pub use self::outline::OutlineStyle;
pub use self::page::{PageName, PageOrientation, PageSize, PageSizeOrientation, PaperSize};
pub use self::percentage::{NonNegativePercentage, Percentage};
pub use self::position::AnchorFunction;
pub use self::position::AnchorName;
pub use self::position::AnchorScope;
pub use self::position::AspectRatio;
pub use self::position::Inset;
pub use self::position::PositionAnchor;
pub use self::position::PositionTryFallbacks;
pub use self::position::PositionTryOrder;
pub use self::position::PositionVisibility;
pub use self::position::{GridAutoFlow, GridTemplateAreas, Position, PositionOrAuto};
pub use self::position::{MasonryAutoFlow, MasonryItemOrder, MasonryPlacement};
pub use self::position::{PositionArea, PositionAreaKeyword};
pub use self::position::{PositionComponent, 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};
pub use self::svg::{SVGPaintOrder, SVGStrokeDashArray, SVGWidth, VectorEffect};
pub use self::svg_path::SVGPathData;
pub use self::text::HyphenateCharacter;
pub use self::text::RubyPosition;
pub use self::text::TextAlignLast;
pub use self::text::TextUnderlinePosition;
pub use self::text::{InitialLetter, LetterSpacing, LineBreak, TextAlign, TextIndent};
pub use self::text::{OverflowWrap, TextEmphasisPosition, TextEmphasisStyle, WordBreak};
pub use self::text::{TextAlignKeyword, TextDecorationLine, TextOverflow, WordSpacing};
pub use self::text::{TextDecorationLength, TextDecorationSkipInk, TextJustify, TextTransform};
pub use self::time::Time;
pub use self::transform::{Rotate, Scale, Transform};
pub use self::transform::{TransformBox, TransformOrigin, TransformStyle, Translate};
#[cfg(feature = "gecko")]
pub use self::ui::CursorImage;
pub use self::ui::{
BoolInteger, Cursor, Inert, MozTheme, PointerEvents, ScrollbarColor, UserFocus, UserInput,
UserSelect,
};
pub use super::generics::grid::GridTemplateComponent as GenericGridTemplateComponent;
pub mod align;
pub mod angle;
pub mod animation;
pub mod background;
pub mod basic_shape;
pub mod border;
#[path = "box.rs"]
pub mod box_;
pub mod calc;
pub mod color;
pub mod column;
pub mod counters;
pub mod easing;
pub mod effects;
pub mod flex;
pub mod font;
#[cfg(feature = "gecko")]
pub mod gecko;
pub mod grid;
pub mod image;
pub mod length;
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 source_size_list;
pub mod svg;
pub mod svg_path;
pub mod table;
pub mod text;
pub mod time;
pub mod transform;
pub mod ui;
pub mod url;
/// <angle> | <percentage>
#[allow(missing_docs)]
#[derive(Clone, Copy, Debug, MallocSizeOf, PartialEq, SpecifiedValueInfo, ToCss, ToShmem)]
pub enum AngleOrPercentage {
Percentage(Percentage),
Angle(Angle),
}
impl AngleOrPercentage {
fn parse_internal<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
allow_unitless_zero: AllowUnitlessZeroAngle,
) -> Result<Self, ParseError<'i>> {
if let Ok(per) = input.try_parse(|i| Percentage::parse(context, i)) {
return Ok(AngleOrPercentage::Percentage(per));
}
Angle::parse_internal(context, input, allow_unitless_zero).map(AngleOrPercentage::Angle)
}
/// Allow unitless angles, used for conic-gradients as specified by the spec.
pub fn parse_with_unitless<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Self, ParseError<'i>> {
AngleOrPercentage::parse_internal(context, input, AllowUnitlessZeroAngle::Yes)
}
}
impl Parse for AngleOrPercentage {
fn parse<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Self, ParseError<'i>> {
AngleOrPercentage::parse_internal(context, input, AllowUnitlessZeroAngle::No)
}
}
/// Parse a `<number>` value, with a given clamping mode.
fn parse_number_with_clamping_mode<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
clamping_mode: AllowedNumericType,
) -> Result<Number, ParseError<'i>> {
let location = input.current_source_location();
match *input.next()? {
Token::Number { value, .. } if clamping_mode.is_ok(context.parsing_mode, value) => {
Ok(Number {
value,
calc_clamping_mode: None,
})
},
Token::Function(ref name) => {
let function = CalcNode::math_function(context, name, location)?;
let value = CalcNode::parse_number(context, input, function)?;
Ok(Number {
value,
calc_clamping_mode: Some(clamping_mode),
})
},
ref t => Err(location.new_unexpected_token_error(t.clone())),
}
}
/// A CSS `<number>` specified value.
///
#[derive(Clone, Copy, Debug, MallocSizeOf, PartialOrd, ToShmem)]
pub struct Number {
/// The numeric value itself.
value: CSSFloat,
/// If this number came from a calc() expression, this tells how clamping
/// should be done on the value.
calc_clamping_mode: Option<AllowedNumericType>,
}
impl Parse for Number {
fn parse<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Self, ParseError<'i>> {
parse_number_with_clamping_mode(context, input, AllowedNumericType::All)
}
}
impl PartialEq<Number> for Number {
fn eq(&self, other: &Number) -> bool {
if self.calc_clamping_mode != other.calc_clamping_mode {
return false;
}
self.value == other.value || (self.value.is_nan() && other.value.is_nan())
}
}
impl Number {
/// Returns a new number with the value `val`.
#[inline]
fn new_with_clamping_mode(
value: CSSFloat,
calc_clamping_mode: Option<AllowedNumericType>,
) -> Self {
Self {
value,
calc_clamping_mode,
}
}
/// Returns this percentage as a number.
pub fn to_percentage(&self) -> Percentage {
Percentage::new_with_clamping_mode(self.value, self.calc_clamping_mode)
}
/// Returns a new number with the value `val`.
#[inline]
pub fn new(val: CSSFloat) -> Self {
Self::new_with_clamping_mode(val, None)
}
/// Returns whether this number came from a `calc()` expression.
#[inline]
pub fn was_calc(&self) -> bool {
self.calc_clamping_mode.is_some()
}
/// Returns the numeric value, clamped if needed.
#[inline]
pub fn get(&self) -> f32 {
crate::values::normalize(
self.calc_clamping_mode
.map_or(self.value, |mode| mode.clamp(self.value)),
)
.min(f32::MAX)
.max(f32::MIN)
}
#[allow(missing_docs)]
pub fn parse_non_negative<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Number, ParseError<'i>> {
parse_number_with_clamping_mode(context, input, AllowedNumericType::NonNegative)
}
#[allow(missing_docs)]
pub fn parse_at_least_one<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Number, ParseError<'i>> {
parse_number_with_clamping_mode(context, input, AllowedNumericType::AtLeastOne)
}
/// Clamp to 1.0 if the value is over 1.0.
#[inline]
pub fn clamp_to_one(self) -> Self {
Number {
value: self.value.min(1.),
calc_clamping_mode: self.calc_clamping_mode,
}
}
}
impl ToComputedValue for Number {
type ComputedValue = CSSFloat;
#[inline]
fn to_computed_value(&self, _: &Context) -> CSSFloat {
self.get()
}
#[inline]
fn from_computed_value(computed: &CSSFloat) -> Self {
Number {
value: *computed,
calc_clamping_mode: None,
}
}
}
impl ToCss for Number {
fn to_css<W>(&self, dest: &mut CssWriter<W>) -> fmt::Result
where
W: Write,
{
serialize_number(self.value, self.calc_clamping_mode.is_some(), dest)
}
}
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.get(), self.1.get(), self.2.get());
self_vector
.cross(*vector)
.square_length()
.approx_eq(&0.0f32)
}
}
impl SpecifiedValueInfo for Number {}
impl Add for Number {
type Output = Self;
fn add(self, other: Self) -> Self {
Self::new(self.get() + other.get())
}
}
impl Zero for Number {
#[inline]
fn zero() -> Self {
Self::new(0.)
}
#[inline]
fn is_zero(&self) -> bool {
self.get() == 0.
}
}
impl From<Number> for f32 {
#[inline]
fn from(n: Number) -> Self {
n.get()
}
}
impl From<Number> for f64 {
#[inline]
fn from(n: Number) -> Self {
n.get() as f64
}
}
/// A Number which is >= 0.0.
pub type NonNegativeNumber = NonNegative<Number>;
impl Parse for NonNegativeNumber {
fn parse<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Self, ParseError<'i>> {
parse_number_with_clamping_mode(context, input, AllowedNumericType::NonNegative)
.map(NonNegative::<Number>)
}
}
impl One for NonNegativeNumber {
#[inline]
fn one() -> Self {
NonNegativeNumber::new(1.0)
}
#[inline]
fn is_one(&self) -> bool {
self.get() == 1.0
}
}
impl NonNegativeNumber {
/// Returns a new non-negative number with the value `val`.
pub fn new(val: CSSFloat) -> Self {
NonNegative::<Number>(Number::new(val.max(0.)))
}
/// Returns the numeric value.
#[inline]
pub fn get(&self) -> f32 {
self.0.get()
}
}
/// An Integer which is >= 0.
pub type NonNegativeInteger = NonNegative<Integer>;
impl Parse for NonNegativeInteger {
fn parse<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Self, ParseError<'i>> {
Ok(NonNegative(Integer::parse_non_negative(context, input)?))
}
}
/// A Number which is >= 1.0.
pub type GreaterThanOrEqualToOneNumber = GreaterThanOrEqualToOne<Number>;
impl Parse for GreaterThanOrEqualToOneNumber {
fn parse<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Self, ParseError<'i>> {
parse_number_with_clamping_mode(context, input, AllowedNumericType::AtLeastOne)
.map(GreaterThanOrEqualToOne::<Number>)
}
}
/// <number> | <percentage>
///
/// Accepts only non-negative numbers.
#[allow(missing_docs)]
#[derive(Clone, Copy, Debug, MallocSizeOf, PartialEq, SpecifiedValueInfo, ToCss, ToShmem)]
pub enum NumberOrPercentage {
Percentage(Percentage),
Number(Number),
}
impl NumberOrPercentage {
fn parse_with_clamping_mode<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
type_: AllowedNumericType,
) -> Result<Self, ParseError<'i>> {
if let Ok(per) =
input.try_parse(|i| Percentage::parse_with_clamping_mode(context, i, type_))
{
return Ok(NumberOrPercentage::Percentage(per));
}
parse_number_with_clamping_mode(context, input, type_).map(NumberOrPercentage::Number)
}
/// Parse a non-negative number or percentage.
pub fn parse_non_negative<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Self, ParseError<'i>> {
Self::parse_with_clamping_mode(context, input, AllowedNumericType::NonNegative)
}
/// Convert the number or the percentage to a number.
pub fn to_percentage(self) -> Percentage {
match self {
Self::Percentage(p) => p,
Self::Number(n) => n.to_percentage(),
}
}
/// Convert the number or the percentage to a number.
pub fn to_number(self) -> Number {
match self {
Self::Percentage(p) => p.to_number(),
Self::Number(n) => n,
}
}
}
impl Parse for NumberOrPercentage {
fn parse<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Self, ParseError<'i>> {
Self::parse_with_clamping_mode(context, input, AllowedNumericType::All)
}
}
/// 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()))
}
/// Return a particular number.
#[inline]
pub fn new_number(n: f32) -> Self {
NonNegative(NumberOrPercentage::Number(Number::new(n)))
}
}
impl Parse for NonNegativeNumberOrPercentage {
fn parse<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Self, ParseError<'i>> {
Ok(NonNegative(NumberOrPercentage::parse_non_negative(
context, input,
)?))
}
}
/// The value of Opacity is <alpha-value>, which is "<number> | <percentage>".
/// However, we serialize the specified value as number, so it's ok to store
/// the Opacity as Number.
#[derive(
Clone, Copy, Debug, MallocSizeOf, PartialEq, PartialOrd, SpecifiedValueInfo, ToCss, ToShmem,
)]
pub struct Opacity(Number);
impl Parse for Opacity {
/// Opacity accepts <number> | <percentage>, so we parse it as NumberOrPercentage,
/// and then convert into an Number if it's a Percentage.
fn parse<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Self, ParseError<'i>> {
let number = NumberOrPercentage::parse(context, input)?.to_number();
Ok(Opacity(number))
}
}
impl ToComputedValue for Opacity {
type ComputedValue = CSSFloat;
#[inline]
fn to_computed_value(&self, context: &Context) -> CSSFloat {
let value = self.0.to_computed_value(context);
if context.for_smil_animation {
// SMIL expects to be able to interpolate between out-of-range
// opacity values.
value
} else {
value.min(1.0).max(0.0)
}
}
#[inline]
fn from_computed_value(computed: &CSSFloat) -> Self {
Opacity(Number::from_computed_value(computed))
}
}
/// A specified `<integer>`, optionally coming from a `calc()` expression.
///
#[derive(Clone, Copy, Debug, Eq, MallocSizeOf, PartialEq, PartialOrd, ToShmem)]
pub struct Integer {
value: CSSInteger,
was_calc: bool,
}
impl Zero for Integer {
#[inline]
fn zero() -> Self {
Self::new(0)
}
#[inline]
fn is_zero(&self) -> bool {
self.value() == 0
}
}
impl One for Integer {
#[inline]
fn one() -> Self {
Self::new(1)
}
#[inline]
fn is_one(&self) -> bool {
self.value() == 1
}
}
impl PartialEq<i32> for Integer {
fn eq(&self, value: &i32) -> bool {
self.value() == *value
}
}
impl Integer {
/// Trivially constructs a new `Integer` value.
pub fn new(val: CSSInteger) -> Self {
Integer {
value: val,
was_calc: false,
}
}
/// Returns the integer value associated with this value.
pub fn value(&self) -> CSSInteger {
self.value
}
/// Trivially constructs a new integer value from a `calc()` expression.
fn from_calc(val: CSSInteger) -> Self {
Integer {
value: val,
was_calc: true,
}
}
}
impl Parse for Integer {
fn parse<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Self, ParseError<'i>> {
let location = input.current_source_location();
match *input.next()? {
Token::Number {
int_value: Some(v), ..
} => Ok(Integer::new(v)),
Token::Function(ref name) => {
let function = CalcNode::math_function(context, name, location)?;
let result = CalcNode::parse_integer(context, input, function)?;
Ok(Integer::from_calc(result))
},
ref t => Err(location.new_unexpected_token_error(t.clone())),
}
}
}
impl Integer {
/// Parse an integer value which is at least `min`.
pub fn parse_with_minimum<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
min: i32,
) -> Result<Integer, ParseError<'i>> {
let value = Integer::parse(context, input)?;
// FIXME(emilio): The spec asks us to avoid rejecting it at parse
// time except until computed value time.
//
// It's not totally clear it's worth it though, and no other browser
// does this.
if value.value() < min {
return Err(input.new_custom_error(StyleParseErrorKind::UnspecifiedError));
}
Ok(value)
}
/// Parse a non-negative integer.
pub fn parse_non_negative<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Integer, ParseError<'i>> {
Integer::parse_with_minimum(context, input, 0)
}
/// Parse a positive integer (>= 1).
pub fn parse_positive<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Integer, ParseError<'i>> {
Integer::parse_with_minimum(context, input, 1)
}
}
impl ToComputedValue for Integer {
type ComputedValue = i32;
#[inline]
fn to_computed_value(&self, _: &Context) -> i32 {
self.value
}
#[inline]
fn from_computed_value(computed: &i32) -> Self {
Integer::new(*computed)
}
}
impl ToCss for Integer {
fn to_css<W>(&self, dest: &mut CssWriter<W>) -> fmt::Result
where
W: Write,
{
if self.was_calc {
dest.write_str("calc(")?;
}
self.value.to_css(dest)?;
if self.was_calc {
dest.write_char(')')?;
}
Ok(())
}
}
impl SpecifiedValueInfo for Integer {}
/// A wrapper of Integer, with value >= 1.
pub type PositiveInteger = GreaterThanOrEqualToOne<Integer>;
impl Parse for PositiveInteger {
#[inline]
fn parse<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Self, ParseError<'i>> {
Integer::parse_positive(context, input).map(GreaterThanOrEqualToOne)
}
}
/// The specified value of a grid `<track-breadth>`
pub type TrackBreadth = GenericTrackBreadth<LengthPercentage>;
/// The specified value of a grid `<track-size>`
pub type TrackSize = GenericTrackSize<LengthPercentage>;
/// The specified value of a grid `<track-size>+`
pub type ImplicitGridTracks = GenericImplicitGridTracks<TrackSize>;
/// The specified value of a grid `<track-list>`
/// (could also be `<auto-track-list>` or `<explicit-track-list>`)
pub type TrackList = GenericTrackList<LengthPercentage, Integer>;
/// The specified value of a `<grid-line>`.
pub type GridLine = GenericGridLine<Integer>;
/// `<grid-template-rows> | <grid-template-columns>`
pub type GridTemplateComponent = GenericGridTemplateComponent<LengthPercentage, Integer>;
/// rect(...)
pub type ClipRect = generics::GenericClipRect<LengthOrAuto>;
impl Parse for ClipRect {
fn parse<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Self, ParseError<'i>> {
Self::parse_quirky(context, input, AllowQuirks::No)
}
}
impl ClipRect {
/// Parses a rect(<top>, <left>, <bottom>, <right>), allowing quirks.
fn parse_quirky<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
allow_quirks: AllowQuirks,
) -> Result<Self, ParseError<'i>> {
input.expect_function_matching("rect")?;
fn parse_argument<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
allow_quirks: AllowQuirks,
) -> Result<LengthOrAuto, ParseError<'i>> {
LengthOrAuto::parse_quirky(context, input, allow_quirks)
}
input.parse_nested_block(|input| {
let top = parse_argument(context, input, allow_quirks)?;
let right;
let bottom;
let left;
if input.try_parse(|input| input.expect_comma()).is_ok() {
right = parse_argument(context, input, allow_quirks)?;
input.expect_comma()?;
bottom = parse_argument(context, input, allow_quirks)?;
input.expect_comma()?;
left = parse_argument(context, input, allow_quirks)?;
} else {
right = parse_argument(context, input, allow_quirks)?;
bottom = parse_argument(context, input, allow_quirks)?;
left = parse_argument(context, input, allow_quirks)?;
}
Ok(ClipRect {
top,
right,
bottom,
left,
})
})
}
}
/// rect(...) | auto
pub type ClipRectOrAuto = generics::GenericClipRectOrAuto<ClipRect>;
impl ClipRectOrAuto {
/// Parses a ClipRect or Auto, allowing quirks.
pub fn parse_quirky<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
allow_quirks: AllowQuirks,
) -> Result<Self, ParseError<'i>> {
if let Ok(v) = input.try_parse(|i| ClipRect::parse_quirky(context, i, allow_quirks)) {
return Ok(generics::GenericClipRectOrAuto::Rect(v));
}
input.expect_ident_matching("auto")?;
Ok(generics::GenericClipRectOrAuto::Auto)
}
}
/// Whether quirks are allowed in this context.
#[derive(Clone, Copy, PartialEq)]
pub enum AllowQuirks {
/// Quirks are not allowed.
No,
/// Quirks are allowed, in quirks mode.
Yes,
/// Quirks are always allowed, used for SVG lengths.
Always,
}
impl AllowQuirks {
/// Returns `true` if quirks are allowed in this context.
pub fn allowed(self, quirks_mode: QuirksMode) -> bool {
match self {
AllowQuirks::Always => true,
AllowQuirks::No => false,
AllowQuirks::Yes => quirks_mode == QuirksMode::Quirks,
}
}
}
/// An attr(...) rule
///
/// `[namespace? `|`]? ident`
#[derive(
Clone,
Debug,
Eq,
MallocSizeOf,
PartialEq,
SpecifiedValueInfo,
ToComputedValue,
ToResolvedValue,
ToShmem,
)]
#[css(function)]
#[repr(C)]
pub struct Attr {
/// Optional namespace prefix.
pub namespace_prefix: Prefix,
/// Optional namespace URL.
pub namespace_url: Namespace,
/// Attribute name
pub attribute: Atom,
/// Fallback value
pub fallback: AtomString,
}
impl Parse for Attr {
fn parse<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Attr, ParseError<'i>> {
input.expect_function_matching("attr")?;
input.parse_nested_block(|i| Attr::parse_function(context, i))
}
}
/// Get the Namespace for a given prefix from the namespace map.
fn get_namespace_for_prefix(prefix: &Prefix, context: &ParserContext) -> Option<Namespace> {
context.namespaces.prefixes.get(prefix).cloned()
}
/// Try to parse a namespace and return it if parsed, or none if there was not one present
fn parse_namespace<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<(Prefix, Namespace), ParseError<'i>> {
let ns_prefix = match input.next()? {
Token::Ident(ref prefix) => Some(Prefix::from(prefix.as_ref())),
Token::Delim('|') => None,
_ => return Err(input.new_custom_error(StyleParseErrorKind::UnspecifiedError)),
};
if ns_prefix.is_some() && !matches!(*input.next_including_whitespace()?, Token::Delim('|')) {
return Err(input.new_custom_error(StyleParseErrorKind::UnspecifiedError));
}
if let Some(prefix) = ns_prefix {
let ns = match get_namespace_for_prefix(&prefix, context) {
Some(ns) => ns,
None => return Err(input.new_custom_error(StyleParseErrorKind::UnspecifiedError)),
};
Ok((prefix, ns))
} else {
Ok((Prefix::default(), Namespace::default()))
}
}
impl Attr {
/// Parse contents of attr() assuming we have already parsed `attr` and are
/// within a parse_nested_block()
pub fn parse_function<'i, 't>(
context: &ParserContext,
input: &mut Parser<'i, 't>,
) -> Result<Attr, ParseError<'i>> {
// Syntax is `[namespace? '|']? ident [',' fallback]?`
let namespace = input
.try_parse(|input| parse_namespace(context, input))
.ok();
let namespace_is_some = namespace.is_some();
let (namespace_prefix, namespace_url) = namespace.unwrap_or_default();
// If there is a namespace, ensure no whitespace following '|'
let attribute = Atom::from(if namespace_is_some {
let location = input.current_source_location();
match *input.next_including_whitespace()? {
Token::Ident(ref ident) => ident.as_ref(),
ref t => return Err(location.new_unexpected_token_error(t.clone())),
}
} else {
input.expect_ident()?.as_ref()
});
// Fallback will always be a string value for now as we do not support
// attr() types yet.
let fallback = input
.try_parse(|input| -> Result<AtomString, ParseError<'i>> {
input.expect_comma()?;
Ok(input.expect_string()?.as_ref().into())
})
.unwrap_or_default();
Ok(Attr {
namespace_prefix,
namespace_url,
attribute,
fallback,
})
}
}
impl ToCss for Attr {
fn to_css<W>(&self, dest: &mut CssWriter<W>) -> fmt::Result
where
W: Write,
{
dest.write_str("attr(")?;
if !self.namespace_prefix.is_empty() {
serialize_atom_identifier(&self.namespace_prefix, dest)?;
dest.write_char('|')?;
}
serialize_atom_identifier(&self.attribute, dest)?;
if !self.fallback.is_empty() {
dest.write_str(", ")?;
self.fallback.to_css(dest)?;
}
dest.write_char(')')
}
}