read_fonts/generated/generated_glyf.rs
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// THIS FILE IS AUTOGENERATED.
// Any changes to this file will be overwritten.
// For more information about how codegen works, see font-codegen/README.md
#[allow(unused_imports)]
use crate::codegen_prelude::*;
/// The [glyf (Glyph Data)](https://docs.microsoft.com/en-us/typography/opentype/spec/glyf) table
#[derive(Debug, Clone, Copy)]
#[doc(hidden)]
pub struct GlyfMarker {}
impl GlyfMarker {}
impl TopLevelTable for Glyf<'_> {
/// `glyf`
const TAG: Tag = Tag::new(b"glyf");
}
impl<'a> FontRead<'a> for Glyf<'a> {
fn read(data: FontData<'a>) -> Result<Self, ReadError> {
let cursor = data.cursor();
cursor.finish(GlyfMarker {})
}
}
/// The [glyf (Glyph Data)](https://docs.microsoft.com/en-us/typography/opentype/spec/glyf) table
pub type Glyf<'a> = TableRef<'a, GlyfMarker>;
impl<'a> Glyf<'a> {}
#[cfg(feature = "experimental_traverse")]
impl<'a> SomeTable<'a> for Glyf<'a> {
fn type_name(&self) -> &str {
"Glyf"
}
#[allow(unused_variables)]
#[allow(clippy::match_single_binding)]
fn get_field(&self, idx: usize) -> Option<Field<'a>> {
match idx {
_ => None,
}
}
}
#[cfg(feature = "experimental_traverse")]
impl<'a> std::fmt::Debug for Glyf<'a> {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
(self as &dyn SomeTable<'a>).fmt(f)
}
}
/// The [Glyph Header](https://docs.microsoft.com/en-us/typography/opentype/spec/glyf#glyph-headers)
#[derive(Debug, Clone, Copy)]
#[doc(hidden)]
pub struct SimpleGlyphMarker {
end_pts_of_contours_byte_len: usize,
instructions_byte_len: usize,
glyph_data_byte_len: usize,
}
impl SimpleGlyphMarker {
pub fn number_of_contours_byte_range(&self) -> Range<usize> {
let start = 0;
start..start + i16::RAW_BYTE_LEN
}
pub fn x_min_byte_range(&self) -> Range<usize> {
let start = self.number_of_contours_byte_range().end;
start..start + i16::RAW_BYTE_LEN
}
pub fn y_min_byte_range(&self) -> Range<usize> {
let start = self.x_min_byte_range().end;
start..start + i16::RAW_BYTE_LEN
}
pub fn x_max_byte_range(&self) -> Range<usize> {
let start = self.y_min_byte_range().end;
start..start + i16::RAW_BYTE_LEN
}
pub fn y_max_byte_range(&self) -> Range<usize> {
let start = self.x_max_byte_range().end;
start..start + i16::RAW_BYTE_LEN
}
pub fn end_pts_of_contours_byte_range(&self) -> Range<usize> {
let start = self.y_max_byte_range().end;
start..start + self.end_pts_of_contours_byte_len
}
pub fn instruction_length_byte_range(&self) -> Range<usize> {
let start = self.end_pts_of_contours_byte_range().end;
start..start + u16::RAW_BYTE_LEN
}
pub fn instructions_byte_range(&self) -> Range<usize> {
let start = self.instruction_length_byte_range().end;
start..start + self.instructions_byte_len
}
pub fn glyph_data_byte_range(&self) -> Range<usize> {
let start = self.instructions_byte_range().end;
start..start + self.glyph_data_byte_len
}
}
impl<'a> FontRead<'a> for SimpleGlyph<'a> {
fn read(data: FontData<'a>) -> Result<Self, ReadError> {
let mut cursor = data.cursor();
let number_of_contours: i16 = cursor.read()?;
cursor.advance::<i16>();
cursor.advance::<i16>();
cursor.advance::<i16>();
cursor.advance::<i16>();
let end_pts_of_contours_byte_len = (number_of_contours as usize)
.checked_mul(u16::RAW_BYTE_LEN)
.ok_or(ReadError::OutOfBounds)?;
cursor.advance_by(end_pts_of_contours_byte_len);
let instruction_length: u16 = cursor.read()?;
let instructions_byte_len = (instruction_length as usize)
.checked_mul(u8::RAW_BYTE_LEN)
.ok_or(ReadError::OutOfBounds)?;
cursor.advance_by(instructions_byte_len);
let glyph_data_byte_len = cursor.remaining_bytes() / u8::RAW_BYTE_LEN * u8::RAW_BYTE_LEN;
cursor.advance_by(glyph_data_byte_len);
cursor.finish(SimpleGlyphMarker {
end_pts_of_contours_byte_len,
instructions_byte_len,
glyph_data_byte_len,
})
}
}
/// The [Glyph Header](https://docs.microsoft.com/en-us/typography/opentype/spec/glyf#glyph-headers)
pub type SimpleGlyph<'a> = TableRef<'a, SimpleGlyphMarker>;
impl<'a> SimpleGlyph<'a> {
/// If the number of contours is greater than or equal to zero,
/// this is a simple glyph. If negative, this is a composite glyph
/// — the value -1 should be used for composite glyphs.
pub fn number_of_contours(&self) -> i16 {
let range = self.shape.number_of_contours_byte_range();
self.data.read_at(range.start).unwrap()
}
/// Minimum x for coordinate data.
pub fn x_min(&self) -> i16 {
let range = self.shape.x_min_byte_range();
self.data.read_at(range.start).unwrap()
}
/// Minimum y for coordinate data.
pub fn y_min(&self) -> i16 {
let range = self.shape.y_min_byte_range();
self.data.read_at(range.start).unwrap()
}
/// Maximum x for coordinate data.
pub fn x_max(&self) -> i16 {
let range = self.shape.x_max_byte_range();
self.data.read_at(range.start).unwrap()
}
/// Maximum y for coordinate data.
pub fn y_max(&self) -> i16 {
let range = self.shape.y_max_byte_range();
self.data.read_at(range.start).unwrap()
}
/// Array of point indices for the last point of each contour,
/// in increasing numeric order
pub fn end_pts_of_contours(&self) -> &'a [BigEndian<u16>] {
let range = self.shape.end_pts_of_contours_byte_range();
self.data.read_array(range).unwrap()
}
/// Total number of bytes for instructions. If instructionLength is
/// zero, no instructions are present for this glyph, and this
/// field is followed directly by the flags field.
pub fn instruction_length(&self) -> u16 {
let range = self.shape.instruction_length_byte_range();
self.data.read_at(range.start).unwrap()
}
/// Array of instruction byte code for the glyph.
pub fn instructions(&self) -> &'a [u8] {
let range = self.shape.instructions_byte_range();
self.data.read_array(range).unwrap()
}
/// the raw data for flags & x/y coordinates
pub fn glyph_data(&self) -> &'a [u8] {
let range = self.shape.glyph_data_byte_range();
self.data.read_array(range).unwrap()
}
}
#[cfg(feature = "experimental_traverse")]
impl<'a> SomeTable<'a> for SimpleGlyph<'a> {
fn type_name(&self) -> &str {
"SimpleGlyph"
}
fn get_field(&self, idx: usize) -> Option<Field<'a>> {
match idx {
0usize => Some(Field::new("number_of_contours", self.number_of_contours())),
1usize => Some(Field::new("x_min", self.x_min())),
2usize => Some(Field::new("y_min", self.y_min())),
3usize => Some(Field::new("x_max", self.x_max())),
4usize => Some(Field::new("y_max", self.y_max())),
5usize => Some(Field::new(
"end_pts_of_contours",
self.end_pts_of_contours(),
)),
6usize => Some(Field::new("instruction_length", self.instruction_length())),
7usize => Some(Field::new("instructions", self.instructions())),
8usize => Some(Field::new("glyph_data", self.glyph_data())),
_ => None,
}
}
}
#[cfg(feature = "experimental_traverse")]
impl<'a> std::fmt::Debug for SimpleGlyph<'a> {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
(self as &dyn SomeTable<'a>).fmt(f)
}
}
/// Flags used in [SimpleGlyph]
#[derive(Clone, Copy, Default, PartialEq, Eq, PartialOrd, Ord, Hash, bytemuck :: AnyBitPattern)]
#[cfg_attr(feature = "serde", derive(serde::Serialize, serde::Deserialize))]
#[repr(transparent)]
pub struct SimpleGlyphFlags {
bits: u8,
}
impl SimpleGlyphFlags {
/// Bit 0: If set, the point is on the curve; otherwise, it is off
/// the curve.
pub const ON_CURVE_POINT: Self = Self { bits: 0x01 };
/// Bit 1: If set, the corresponding x-coordinate is 1 byte long,
/// and the sign is determined by the
/// X_IS_SAME_OR_POSITIVE_X_SHORT_VECTOR flag. If not set, its
/// interpretation depends on the
/// X_IS_SAME_OR_POSITIVE_X_SHORT_VECTOR flag: If that other flag
/// is set, the x-coordinate is the same as the previous
/// x-coordinate, and no element is added to the xCoordinates
/// array. If both flags are not set, the corresponding element in
/// the xCoordinates array is two bytes and interpreted as a signed
/// integer. See the description of the
/// X_IS_SAME_OR_POSITIVE_X_SHORT_VECTOR flag for additional
/// information.
pub const X_SHORT_VECTOR: Self = Self { bits: 0x02 };
/// Bit 2: If set, the corresponding y-coordinate is 1 byte long,
/// and the sign is determined by the
/// Y_IS_SAME_OR_POSITIVE_Y_SHORT_VECTOR flag. If not set, its
/// interpretation depends on the
/// Y_IS_SAME_OR_POSITIVE_Y_SHORT_VECTOR flag: If that other flag
/// is set, the y-coordinate is the same as the previous
/// y-coordinate, and no element is added to the yCoordinates
/// array. If both flags are not set, the corresponding element in
/// the yCoordinates array is two bytes and interpreted as a signed
/// integer. See the description of the
/// Y_IS_SAME_OR_POSITIVE_Y_SHORT_VECTOR flag for additional
/// information.
pub const Y_SHORT_VECTOR: Self = Self { bits: 0x04 };
/// Bit 3: If set, the next byte (read as unsigned) specifies the
/// number of additional times this flag byte is to be repeated in
/// the logical flags array — that is, the number of additional
/// logical flag entries inserted after this entry. (In the
/// expanded logical array, this bit is ignored.) In this way, the
/// number of flags listed can be smaller than the number of points
/// in the glyph description.
pub const REPEAT_FLAG: Self = Self { bits: 0x08 };
/// Bit 4: This flag has two meanings, depending on how the
/// X_SHORT_VECTOR flag is set. If X_SHORT_VECTOR is set, this bit
/// describes the sign of the value, with 1 equalling positive and
/// 0 negative. If X_SHORT_VECTOR is not set and this bit is set,
/// then the current x-coordinate is the same as the previous
/// x-coordinate. If X_SHORT_VECTOR is not set and this bit is also
/// not set, the current x-coordinate is a signed 16-bit delta
/// vector.
pub const X_IS_SAME_OR_POSITIVE_X_SHORT_VECTOR: Self = Self { bits: 0x10 };
/// Bit 5: This flag has two meanings, depending on how the
/// Y_SHORT_VECTOR flag is set. If Y_SHORT_VECTOR is set, this bit
/// describes the sign of the value, with 1 equalling positive and
/// 0 negative. If Y_SHORT_VECTOR is not set and this bit is set,
/// then the current y-coordinate is the same as the previous
/// y-coordinate. If Y_SHORT_VECTOR is not set and this bit is also
/// not set, the current y-coordinate is a signed 16-bit delta
/// vector.
pub const Y_IS_SAME_OR_POSITIVE_Y_SHORT_VECTOR: Self = Self { bits: 0x20 };
/// Bit 6: If set, contours in the glyph description may overlap.
/// Use of this flag is not required in OpenType — that is, it is
/// valid to have contours overlap without having this flag set. It
/// may affect behaviors in some platforms, however. (See the
/// discussion of “Overlapping contours” in Apple’s
/// specification for details regarding behavior in Apple
/// platforms.) When used, it must be set on the first flag byte
/// for the glyph. See additional details below.
pub const OVERLAP_SIMPLE: Self = Self { bits: 0x40 };
/// Bit 7: Off-curve point belongs to a cubic-Bezier segment
///
/// * [Spec](https://github.com/harfbuzz/boring-expansion-spec/blob/main/glyf1-cubicOutlines.md)
/// * [harfbuzz](https://github.com/harfbuzz/harfbuzz/blob/c1ca46e4ebb6457dfe00a5441d52a4a66134ac58/src/OT/glyf/SimpleGlyph.hh#L23)
pub const CUBIC: Self = Self { bits: 0x80 };
}
impl SimpleGlyphFlags {
/// Returns an empty set of flags.
#[inline]
pub const fn empty() -> Self {
Self { bits: 0 }
}
/// Returns the set containing all flags.
#[inline]
pub const fn all() -> Self {
Self {
bits: Self::ON_CURVE_POINT.bits
| Self::X_SHORT_VECTOR.bits
| Self::Y_SHORT_VECTOR.bits
| Self::REPEAT_FLAG.bits
| Self::X_IS_SAME_OR_POSITIVE_X_SHORT_VECTOR.bits
| Self::Y_IS_SAME_OR_POSITIVE_Y_SHORT_VECTOR.bits
| Self::OVERLAP_SIMPLE.bits
| Self::CUBIC.bits,
}
}
/// Returns the raw value of the flags currently stored.
#[inline]
pub const fn bits(&self) -> u8 {
self.bits
}
/// Convert from underlying bit representation, unless that
/// representation contains bits that do not correspond to a flag.
#[inline]
pub const fn from_bits(bits: u8) -> Option<Self> {
if (bits & !Self::all().bits()) == 0 {
Some(Self { bits })
} else {
None
}
}
/// Convert from underlying bit representation, dropping any bits
/// that do not correspond to flags.
#[inline]
pub const fn from_bits_truncate(bits: u8) -> Self {
Self {
bits: bits & Self::all().bits,
}
}
/// Returns `true` if no flags are currently stored.
#[inline]
pub const fn is_empty(&self) -> bool {
self.bits() == Self::empty().bits()
}
/// Returns `true` if there are flags common to both `self` and `other`.
#[inline]
pub const fn intersects(&self, other: Self) -> bool {
!(Self {
bits: self.bits & other.bits,
})
.is_empty()
}
/// Returns `true` if all of the flags in `other` are contained within `self`.
#[inline]
pub const fn contains(&self, other: Self) -> bool {
(self.bits & other.bits) == other.bits
}
/// Inserts the specified flags in-place.
#[inline]
pub fn insert(&mut self, other: Self) {
self.bits |= other.bits;
}
/// Removes the specified flags in-place.
#[inline]
pub fn remove(&mut self, other: Self) {
self.bits &= !other.bits;
}
/// Toggles the specified flags in-place.
#[inline]
pub fn toggle(&mut self, other: Self) {
self.bits ^= other.bits;
}
/// Returns the intersection between the flags in `self` and
/// `other`.
///
/// Specifically, the returned set contains only the flags which are
/// present in *both* `self` *and* `other`.
///
/// This is equivalent to using the `&` operator (e.g.
/// [`ops::BitAnd`]), as in `flags & other`.
///
/// [`ops::BitAnd`]: https://doc.rust-lang.org/std/ops/trait.BitAnd.html
#[inline]
#[must_use]
pub const fn intersection(self, other: Self) -> Self {
Self {
bits: self.bits & other.bits,
}
}
/// Returns the union of between the flags in `self` and `other`.
///
/// Specifically, the returned set contains all flags which are
/// present in *either* `self` *or* `other`, including any which are
/// present in both.
///
/// This is equivalent to using the `|` operator (e.g.
/// [`ops::BitOr`]), as in `flags | other`.
///
/// [`ops::BitOr`]: https://doc.rust-lang.org/std/ops/trait.BitOr.html
#[inline]
#[must_use]
pub const fn union(self, other: Self) -> Self {
Self {
bits: self.bits | other.bits,
}
}
/// Returns the difference between the flags in `self` and `other`.
///
/// Specifically, the returned set contains all flags present in
/// `self`, except for the ones present in `other`.
///
/// It is also conceptually equivalent to the "bit-clear" operation:
/// `flags & !other` (and this syntax is also supported).
///
/// This is equivalent to using the `-` operator (e.g.
/// [`ops::Sub`]), as in `flags - other`.
///
/// [`ops::Sub`]: https://doc.rust-lang.org/std/ops/trait.Sub.html
#[inline]
#[must_use]
pub const fn difference(self, other: Self) -> Self {
Self {
bits: self.bits & !other.bits,
}
}
}
impl std::ops::BitOr for SimpleGlyphFlags {
type Output = Self;
/// Returns the union of the two sets of flags.
#[inline]
fn bitor(self, other: SimpleGlyphFlags) -> Self {
Self {
bits: self.bits | other.bits,
}
}
}
impl std::ops::BitOrAssign for SimpleGlyphFlags {
/// Adds the set of flags.
#[inline]
fn bitor_assign(&mut self, other: Self) {
self.bits |= other.bits;
}
}
impl std::ops::BitXor for SimpleGlyphFlags {
type Output = Self;
/// Returns the left flags, but with all the right flags toggled.
#[inline]
fn bitxor(self, other: Self) -> Self {
Self {
bits: self.bits ^ other.bits,
}
}
}
impl std::ops::BitXorAssign for SimpleGlyphFlags {
/// Toggles the set of flags.
#[inline]
fn bitxor_assign(&mut self, other: Self) {
self.bits ^= other.bits;
}
}
impl std::ops::BitAnd for SimpleGlyphFlags {
type Output = Self;
/// Returns the intersection between the two sets of flags.
#[inline]
fn bitand(self, other: Self) -> Self {
Self {
bits: self.bits & other.bits,
}
}
}
impl std::ops::BitAndAssign for SimpleGlyphFlags {
/// Disables all flags disabled in the set.
#[inline]
fn bitand_assign(&mut self, other: Self) {
self.bits &= other.bits;
}
}
impl std::ops::Sub for SimpleGlyphFlags {
type Output = Self;
/// Returns the set difference of the two sets of flags.
#[inline]
fn sub(self, other: Self) -> Self {
Self {
bits: self.bits & !other.bits,
}
}
}
impl std::ops::SubAssign for SimpleGlyphFlags {
/// Disables all flags enabled in the set.
#[inline]
fn sub_assign(&mut self, other: Self) {
self.bits &= !other.bits;
}
}
impl std::ops::Not for SimpleGlyphFlags {
type Output = Self;
/// Returns the complement of this set of flags.
#[inline]
fn not(self) -> Self {
Self { bits: !self.bits } & Self::all()
}
}
impl std::fmt::Debug for SimpleGlyphFlags {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
let members: &[(&str, Self)] = &[
("ON_CURVE_POINT", Self::ON_CURVE_POINT),
("X_SHORT_VECTOR", Self::X_SHORT_VECTOR),
("Y_SHORT_VECTOR", Self::Y_SHORT_VECTOR),
("REPEAT_FLAG", Self::REPEAT_FLAG),
(
"X_IS_SAME_OR_POSITIVE_X_SHORT_VECTOR",
Self::X_IS_SAME_OR_POSITIVE_X_SHORT_VECTOR,
),
(
"Y_IS_SAME_OR_POSITIVE_Y_SHORT_VECTOR",
Self::Y_IS_SAME_OR_POSITIVE_Y_SHORT_VECTOR,
),
("OVERLAP_SIMPLE", Self::OVERLAP_SIMPLE),
("CUBIC", Self::CUBIC),
];
let mut first = true;
for (name, value) in members {
if self.contains(*value) {
if !first {
f.write_str(" | ")?;
}
first = false;
f.write_str(name)?;
}
}
if first {
f.write_str("(empty)")?;
}
Ok(())
}
}
impl std::fmt::Binary for SimpleGlyphFlags {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
std::fmt::Binary::fmt(&self.bits, f)
}
}
impl std::fmt::Octal for SimpleGlyphFlags {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
std::fmt::Octal::fmt(&self.bits, f)
}
}
impl std::fmt::LowerHex for SimpleGlyphFlags {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
std::fmt::LowerHex::fmt(&self.bits, f)
}
}
impl std::fmt::UpperHex for SimpleGlyphFlags {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
std::fmt::UpperHex::fmt(&self.bits, f)
}
}
impl font_types::Scalar for SimpleGlyphFlags {
type Raw = <u8 as font_types::Scalar>::Raw;
fn to_raw(self) -> Self::Raw {
self.bits().to_raw()
}
fn from_raw(raw: Self::Raw) -> Self {
let t = <u8>::from_raw(raw);
Self::from_bits_truncate(t)
}
}
#[cfg(feature = "experimental_traverse")]
impl<'a> From<SimpleGlyphFlags> for FieldType<'a> {
fn from(src: SimpleGlyphFlags) -> FieldType<'a> {
src.bits().into()
}
}
/// [CompositeGlyph](https://docs.microsoft.com/en-us/typography/opentype/spec/glyf#glyph-headers)
#[derive(Debug, Clone, Copy)]
#[doc(hidden)]
pub struct CompositeGlyphMarker {
component_data_byte_len: usize,
}
impl CompositeGlyphMarker {
pub fn number_of_contours_byte_range(&self) -> Range<usize> {
let start = 0;
start..start + i16::RAW_BYTE_LEN
}
pub fn x_min_byte_range(&self) -> Range<usize> {
let start = self.number_of_contours_byte_range().end;
start..start + i16::RAW_BYTE_LEN
}
pub fn y_min_byte_range(&self) -> Range<usize> {
let start = self.x_min_byte_range().end;
start..start + i16::RAW_BYTE_LEN
}
pub fn x_max_byte_range(&self) -> Range<usize> {
let start = self.y_min_byte_range().end;
start..start + i16::RAW_BYTE_LEN
}
pub fn y_max_byte_range(&self) -> Range<usize> {
let start = self.x_max_byte_range().end;
start..start + i16::RAW_BYTE_LEN
}
pub fn component_data_byte_range(&self) -> Range<usize> {
let start = self.y_max_byte_range().end;
start..start + self.component_data_byte_len
}
}
impl<'a> FontRead<'a> for CompositeGlyph<'a> {
fn read(data: FontData<'a>) -> Result<Self, ReadError> {
let mut cursor = data.cursor();
cursor.advance::<i16>();
cursor.advance::<i16>();
cursor.advance::<i16>();
cursor.advance::<i16>();
cursor.advance::<i16>();
let component_data_byte_len =
cursor.remaining_bytes() / u8::RAW_BYTE_LEN * u8::RAW_BYTE_LEN;
cursor.advance_by(component_data_byte_len);
cursor.finish(CompositeGlyphMarker {
component_data_byte_len,
})
}
}
/// [CompositeGlyph](https://docs.microsoft.com/en-us/typography/opentype/spec/glyf#glyph-headers)
pub type CompositeGlyph<'a> = TableRef<'a, CompositeGlyphMarker>;
impl<'a> CompositeGlyph<'a> {
/// If the number of contours is greater than or equal to zero,
/// this is a simple glyph. If negative, this is a composite glyph
/// — the value -1 should be used for composite glyphs.
pub fn number_of_contours(&self) -> i16 {
let range = self.shape.number_of_contours_byte_range();
self.data.read_at(range.start).unwrap()
}
/// Minimum x for coordinate data.
pub fn x_min(&self) -> i16 {
let range = self.shape.x_min_byte_range();
self.data.read_at(range.start).unwrap()
}
/// Minimum y for coordinate data.
pub fn y_min(&self) -> i16 {
let range = self.shape.y_min_byte_range();
self.data.read_at(range.start).unwrap()
}
/// Maximum x for coordinate data.
pub fn x_max(&self) -> i16 {
let range = self.shape.x_max_byte_range();
self.data.read_at(range.start).unwrap()
}
/// Maximum y for coordinate data.
pub fn y_max(&self) -> i16 {
let range = self.shape.y_max_byte_range();
self.data.read_at(range.start).unwrap()
}
/// component flag
/// glyph index of component
pub fn component_data(&self) -> &'a [u8] {
let range = self.shape.component_data_byte_range();
self.data.read_array(range).unwrap()
}
}
#[cfg(feature = "experimental_traverse")]
impl<'a> SomeTable<'a> for CompositeGlyph<'a> {
fn type_name(&self) -> &str {
"CompositeGlyph"
}
fn get_field(&self, idx: usize) -> Option<Field<'a>> {
match idx {
0usize => Some(Field::new("number_of_contours", self.number_of_contours())),
1usize => Some(Field::new("x_min", self.x_min())),
2usize => Some(Field::new("y_min", self.y_min())),
3usize => Some(Field::new("x_max", self.x_max())),
4usize => Some(Field::new("y_max", self.y_max())),
5usize => Some(Field::new("component_data", self.component_data())),
_ => None,
}
}
}
#[cfg(feature = "experimental_traverse")]
impl<'a> std::fmt::Debug for CompositeGlyph<'a> {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
(self as &dyn SomeTable<'a>).fmt(f)
}
}
/// Flags used in [CompositeGlyph]
#[derive(Clone, Copy, Default, PartialEq, Eq, PartialOrd, Ord, Hash, bytemuck :: AnyBitPattern)]
#[cfg_attr(feature = "serde", derive(serde::Serialize, serde::Deserialize))]
#[repr(transparent)]
pub struct CompositeGlyphFlags {
bits: u16,
}
impl CompositeGlyphFlags {
/// Bit 0: If this is set, the arguments are 16-bit (uint16 or
/// int16); otherwise, they are bytes (uint8 or int8).
pub const ARG_1_AND_2_ARE_WORDS: Self = Self { bits: 0x0001 };
/// Bit 1: If this is set, the arguments are signed xy values;
/// otherwise, they are unsigned point numbers.
pub const ARGS_ARE_XY_VALUES: Self = Self { bits: 0x0002 };
/// Bit 2: If set and ARGS_ARE_XY_VALUES is also set, the xy values
/// are rounded to the nearest grid line. Ignored if
/// ARGS_ARE_XY_VALUES is not set.
pub const ROUND_XY_TO_GRID: Self = Self { bits: 0x0004 };
/// Bit 3: This indicates that there is a simple scale for the
/// component. Otherwise, scale = 1.0.
pub const WE_HAVE_A_SCALE: Self = Self { bits: 0x0008 };
/// Bit 5: Indicates at least one more glyph after this one.
pub const MORE_COMPONENTS: Self = Self { bits: 0x0020 };
/// Bit 6: The x direction will use a different scale from the y
/// direction.
pub const WE_HAVE_AN_X_AND_Y_SCALE: Self = Self { bits: 0x0040 };
/// Bit 7: There is a 2 by 2 transformation that will be used to
/// scale the component.
pub const WE_HAVE_A_TWO_BY_TWO: Self = Self { bits: 0x0080 };
/// Bit 8: Following the last component are instructions for the
/// composite character.
pub const WE_HAVE_INSTRUCTIONS: Self = Self { bits: 0x0100 };
/// Bit 9: If set, this forces the aw and lsb (and rsb) for the
/// composite to be equal to those from this component glyph. This
/// works for hinted and unhinted glyphs.
pub const USE_MY_METRICS: Self = Self { bits: 0x0200 };
/// Bit 10: If set, the components of the compound glyph overlap.
/// Use of this flag is not required in OpenType — that is, it is
/// valid to have components overlap without having this flag set.
/// It may affect behaviors in some platforms, however. (See
/// Apple’s specification for details regarding behavior in Apple
/// platforms.) When used, it must be set on the flag word for the
/// first component. See additional remarks, above, for the similar
/// OVERLAP_SIMPLE flag used in simple-glyph descriptions.
pub const OVERLAP_COMPOUND: Self = Self { bits: 0x0400 };
/// Bit 11: The composite is designed to have the component offset
/// scaled. Ignored if ARGS_ARE_XY_VALUES is not set.
pub const SCALED_COMPONENT_OFFSET: Self = Self { bits: 0x0800 };
/// Bit 12: The composite is designed not to have the component
/// offset scaled. Ignored if ARGS_ARE_XY_VALUES is not set.
pub const UNSCALED_COMPONENT_OFFSET: Self = Self { bits: 0x1000 };
}
impl CompositeGlyphFlags {
/// Returns an empty set of flags.
#[inline]
pub const fn empty() -> Self {
Self { bits: 0 }
}
/// Returns the set containing all flags.
#[inline]
pub const fn all() -> Self {
Self {
bits: Self::ARG_1_AND_2_ARE_WORDS.bits
| Self::ARGS_ARE_XY_VALUES.bits
| Self::ROUND_XY_TO_GRID.bits
| Self::WE_HAVE_A_SCALE.bits
| Self::MORE_COMPONENTS.bits
| Self::WE_HAVE_AN_X_AND_Y_SCALE.bits
| Self::WE_HAVE_A_TWO_BY_TWO.bits
| Self::WE_HAVE_INSTRUCTIONS.bits
| Self::USE_MY_METRICS.bits
| Self::OVERLAP_COMPOUND.bits
| Self::SCALED_COMPONENT_OFFSET.bits
| Self::UNSCALED_COMPONENT_OFFSET.bits,
}
}
/// Returns the raw value of the flags currently stored.
#[inline]
pub const fn bits(&self) -> u16 {
self.bits
}
/// Convert from underlying bit representation, unless that
/// representation contains bits that do not correspond to a flag.
#[inline]
pub const fn from_bits(bits: u16) -> Option<Self> {
if (bits & !Self::all().bits()) == 0 {
Some(Self { bits })
} else {
None
}
}
/// Convert from underlying bit representation, dropping any bits
/// that do not correspond to flags.
#[inline]
pub const fn from_bits_truncate(bits: u16) -> Self {
Self {
bits: bits & Self::all().bits,
}
}
/// Returns `true` if no flags are currently stored.
#[inline]
pub const fn is_empty(&self) -> bool {
self.bits() == Self::empty().bits()
}
/// Returns `true` if there are flags common to both `self` and `other`.
#[inline]
pub const fn intersects(&self, other: Self) -> bool {
!(Self {
bits: self.bits & other.bits,
})
.is_empty()
}
/// Returns `true` if all of the flags in `other` are contained within `self`.
#[inline]
pub const fn contains(&self, other: Self) -> bool {
(self.bits & other.bits) == other.bits
}
/// Inserts the specified flags in-place.
#[inline]
pub fn insert(&mut self, other: Self) {
self.bits |= other.bits;
}
/// Removes the specified flags in-place.
#[inline]
pub fn remove(&mut self, other: Self) {
self.bits &= !other.bits;
}
/// Toggles the specified flags in-place.
#[inline]
pub fn toggle(&mut self, other: Self) {
self.bits ^= other.bits;
}
/// Returns the intersection between the flags in `self` and
/// `other`.
///
/// Specifically, the returned set contains only the flags which are
/// present in *both* `self` *and* `other`.
///
/// This is equivalent to using the `&` operator (e.g.
/// [`ops::BitAnd`]), as in `flags & other`.
///
/// [`ops::BitAnd`]: https://doc.rust-lang.org/std/ops/trait.BitAnd.html
#[inline]
#[must_use]
pub const fn intersection(self, other: Self) -> Self {
Self {
bits: self.bits & other.bits,
}
}
/// Returns the union of between the flags in `self` and `other`.
///
/// Specifically, the returned set contains all flags which are
/// present in *either* `self` *or* `other`, including any which are
/// present in both.
///
/// This is equivalent to using the `|` operator (e.g.
/// [`ops::BitOr`]), as in `flags | other`.
///
/// [`ops::BitOr`]: https://doc.rust-lang.org/std/ops/trait.BitOr.html
#[inline]
#[must_use]
pub const fn union(self, other: Self) -> Self {
Self {
bits: self.bits | other.bits,
}
}
/// Returns the difference between the flags in `self` and `other`.
///
/// Specifically, the returned set contains all flags present in
/// `self`, except for the ones present in `other`.
///
/// It is also conceptually equivalent to the "bit-clear" operation:
/// `flags & !other` (and this syntax is also supported).
///
/// This is equivalent to using the `-` operator (e.g.
/// [`ops::Sub`]), as in `flags - other`.
///
/// [`ops::Sub`]: https://doc.rust-lang.org/std/ops/trait.Sub.html
#[inline]
#[must_use]
pub const fn difference(self, other: Self) -> Self {
Self {
bits: self.bits & !other.bits,
}
}
}
impl std::ops::BitOr for CompositeGlyphFlags {
type Output = Self;
/// Returns the union of the two sets of flags.
#[inline]
fn bitor(self, other: CompositeGlyphFlags) -> Self {
Self {
bits: self.bits | other.bits,
}
}
}
impl std::ops::BitOrAssign for CompositeGlyphFlags {
/// Adds the set of flags.
#[inline]
fn bitor_assign(&mut self, other: Self) {
self.bits |= other.bits;
}
}
impl std::ops::BitXor for CompositeGlyphFlags {
type Output = Self;
/// Returns the left flags, but with all the right flags toggled.
#[inline]
fn bitxor(self, other: Self) -> Self {
Self {
bits: self.bits ^ other.bits,
}
}
}
impl std::ops::BitXorAssign for CompositeGlyphFlags {
/// Toggles the set of flags.
#[inline]
fn bitxor_assign(&mut self, other: Self) {
self.bits ^= other.bits;
}
}
impl std::ops::BitAnd for CompositeGlyphFlags {
type Output = Self;
/// Returns the intersection between the two sets of flags.
#[inline]
fn bitand(self, other: Self) -> Self {
Self {
bits: self.bits & other.bits,
}
}
}
impl std::ops::BitAndAssign for CompositeGlyphFlags {
/// Disables all flags disabled in the set.
#[inline]
fn bitand_assign(&mut self, other: Self) {
self.bits &= other.bits;
}
}
impl std::ops::Sub for CompositeGlyphFlags {
type Output = Self;
/// Returns the set difference of the two sets of flags.
#[inline]
fn sub(self, other: Self) -> Self {
Self {
bits: self.bits & !other.bits,
}
}
}
impl std::ops::SubAssign for CompositeGlyphFlags {
/// Disables all flags enabled in the set.
#[inline]
fn sub_assign(&mut self, other: Self) {
self.bits &= !other.bits;
}
}
impl std::ops::Not for CompositeGlyphFlags {
type Output = Self;
/// Returns the complement of this set of flags.
#[inline]
fn not(self) -> Self {
Self { bits: !self.bits } & Self::all()
}
}
impl std::fmt::Debug for CompositeGlyphFlags {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
let members: &[(&str, Self)] = &[
("ARG_1_AND_2_ARE_WORDS", Self::ARG_1_AND_2_ARE_WORDS),
("ARGS_ARE_XY_VALUES", Self::ARGS_ARE_XY_VALUES),
("ROUND_XY_TO_GRID", Self::ROUND_XY_TO_GRID),
("WE_HAVE_A_SCALE", Self::WE_HAVE_A_SCALE),
("MORE_COMPONENTS", Self::MORE_COMPONENTS),
("WE_HAVE_AN_X_AND_Y_SCALE", Self::WE_HAVE_AN_X_AND_Y_SCALE),
("WE_HAVE_A_TWO_BY_TWO", Self::WE_HAVE_A_TWO_BY_TWO),
("WE_HAVE_INSTRUCTIONS", Self::WE_HAVE_INSTRUCTIONS),
("USE_MY_METRICS", Self::USE_MY_METRICS),
("OVERLAP_COMPOUND", Self::OVERLAP_COMPOUND),
("SCALED_COMPONENT_OFFSET", Self::SCALED_COMPONENT_OFFSET),
("UNSCALED_COMPONENT_OFFSET", Self::UNSCALED_COMPONENT_OFFSET),
];
let mut first = true;
for (name, value) in members {
if self.contains(*value) {
if !first {
f.write_str(" | ")?;
}
first = false;
f.write_str(name)?;
}
}
if first {
f.write_str("(empty)")?;
}
Ok(())
}
}
impl std::fmt::Binary for CompositeGlyphFlags {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
std::fmt::Binary::fmt(&self.bits, f)
}
}
impl std::fmt::Octal for CompositeGlyphFlags {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
std::fmt::Octal::fmt(&self.bits, f)
}
}
impl std::fmt::LowerHex for CompositeGlyphFlags {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
std::fmt::LowerHex::fmt(&self.bits, f)
}
}
impl std::fmt::UpperHex for CompositeGlyphFlags {
fn fmt(&self, f: &mut std::fmt::Formatter) -> std::fmt::Result {
std::fmt::UpperHex::fmt(&self.bits, f)
}
}
impl font_types::Scalar for CompositeGlyphFlags {
type Raw = <u16 as font_types::Scalar>::Raw;
fn to_raw(self) -> Self::Raw {
self.bits().to_raw()
}
fn from_raw(raw: Self::Raw) -> Self {
let t = <u16>::from_raw(raw);
Self::from_bits_truncate(t)
}
}
#[cfg(feature = "experimental_traverse")]
impl<'a> From<CompositeGlyphFlags> for FieldType<'a> {
fn from(src: CompositeGlyphFlags) -> FieldType<'a> {
src.bits().into()
}
}
/// Simple or composite glyph.
#[derive(Clone)]
pub enum Glyph<'a> {
Simple(SimpleGlyph<'a>),
Composite(CompositeGlyph<'a>),
}
impl<'a> Glyph<'a> {
///Return the `FontData` used to resolve offsets for this table.
pub fn offset_data(&self) -> FontData<'a> {
match self {
Self::Simple(item) => item.offset_data(),
Self::Composite(item) => item.offset_data(),
}
}
/// If the number of contours is greater than or equal to zero,
/// this is a simple glyph. If negative, this is a composite glyph
/// — the value -1 should be used for composite glyphs.
pub fn number_of_contours(&self) -> i16 {
match self {
Self::Simple(item) => item.number_of_contours(),
Self::Composite(item) => item.number_of_contours(),
}
}
/// Minimum x for coordinate data.
pub fn x_min(&self) -> i16 {
match self {
Self::Simple(item) => item.x_min(),
Self::Composite(item) => item.x_min(),
}
}
/// Minimum y for coordinate data.
pub fn y_min(&self) -> i16 {
match self {
Self::Simple(item) => item.y_min(),
Self::Composite(item) => item.y_min(),
}
}
/// Maximum x for coordinate data.
pub fn x_max(&self) -> i16 {
match self {
Self::Simple(item) => item.x_max(),
Self::Composite(item) => item.x_max(),
}
}
/// Maximum y for coordinate data.
pub fn y_max(&self) -> i16 {
match self {
Self::Simple(item) => item.y_max(),
Self::Composite(item) => item.y_max(),
}
}
}
impl<'a> FontRead<'a> for Glyph<'a> {
fn read(data: FontData<'a>) -> Result<Self, ReadError> {
let format: i16 = data.read_at(0usize)?;
#[allow(clippy::redundant_guards)]
match format {
format if format >= 0 => Ok(Self::Simple(FontRead::read(data)?)),
format if format < 0 => Ok(Self::Composite(FontRead::read(data)?)),
other => Err(ReadError::InvalidFormat(other.into())),
}
}
}
#[cfg(feature = "experimental_traverse")]
impl<'a> Glyph<'a> {
fn dyn_inner<'b>(&'b self) -> &'b dyn SomeTable<'a> {
match self {
Self::Simple(table) => table,
Self::Composite(table) => table,
}
}
}
#[cfg(feature = "experimental_traverse")]
impl<'a> std::fmt::Debug for Glyph<'a> {
fn fmt(&self, f: &mut std::fmt::Formatter<'_>) -> std::fmt::Result {
self.dyn_inner().fmt(f)
}
}
#[cfg(feature = "experimental_traverse")]
impl<'a> SomeTable<'a> for Glyph<'a> {
fn type_name(&self) -> &str {
self.dyn_inner().type_name()
}
fn get_field(&self, idx: usize) -> Option<Field<'a>> {
self.dyn_inner().get_field(idx)
}
}