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|
use std::collections::{BTreeMap, HashMap};
use std::hash::Hash;
use std::sync::Arc;
use ecow::{eco_format, EcoString};
use pdf_writer::{
types::{CidFontType, FontFlags, SystemInfo, UnicodeCmap},
writers::FontDescriptor,
Chunk, Filter, Finish, Name, Rect, Ref, Str,
};
use ttf_parser::{name_id, GlyphId, Tag};
use typst::text::Font;
use typst::utils::SliceExt;
use unicode_properties::{GeneralCategory, UnicodeGeneralCategory};
use crate::{deflate, EmExt, PdfChunk, WithGlobalRefs};
const CFF: Tag = Tag::from_bytes(b"CFF ");
const CFF2: Tag = Tag::from_bytes(b"CFF2");
pub(crate) const CMAP_NAME: Name = Name(b"Custom");
pub(crate) const SYSTEM_INFO: SystemInfo = SystemInfo {
registry: Str(b"Adobe"),
ordering: Str(b"Identity"),
supplement: 0,
};
/// Embed all used fonts into the PDF.
#[typst_macros::time(name = "write fonts")]
pub fn write_fonts(context: &WithGlobalRefs) -> (PdfChunk, HashMap<Font, Ref>) {
let mut chunk = PdfChunk::new();
let mut out = HashMap::new();
context.resources.traverse(&mut |resources| {
for font in resources.fonts.items() {
if out.contains_key(font) {
continue;
}
let type0_ref = chunk.alloc();
let cid_ref = chunk.alloc();
let descriptor_ref = chunk.alloc();
let cmap_ref = chunk.alloc();
let data_ref = chunk.alloc();
out.insert(font.clone(), type0_ref);
let glyph_set = resources.glyph_sets.get(font).unwrap();
let ttf = font.ttf();
// Do we have a TrueType or CFF font?
//
// FIXME: CFF2 must be handled differently and requires PDF 2.0
// (or we have to convert it to CFF).
let is_cff = ttf
.raw_face()
.table(CFF)
.or_else(|| ttf.raw_face().table(CFF2))
.is_some();
let postscript_name = font
.find_name(name_id::POST_SCRIPT_NAME)
.unwrap_or_else(|| "unknown".to_string());
let subset_tag = subset_tag(glyph_set);
let base_font = eco_format!("{subset_tag}+{postscript_name}");
let base_font_type0 = if is_cff {
eco_format!("{base_font}-Identity-H")
} else {
base_font.clone()
};
// Write the base font object referencing the CID font.
chunk
.type0_font(type0_ref)
.base_font(Name(base_font_type0.as_bytes()))
.encoding_predefined(Name(b"Identity-H"))
.descendant_font(cid_ref)
.to_unicode(cmap_ref);
// Write the CID font referencing the font descriptor.
let mut cid = chunk.cid_font(cid_ref);
cid.subtype(if is_cff { CidFontType::Type0 } else { CidFontType::Type2 });
cid.base_font(Name(base_font.as_bytes()));
cid.system_info(SYSTEM_INFO);
cid.font_descriptor(descriptor_ref);
cid.default_width(0.0);
if !is_cff {
cid.cid_to_gid_map_predefined(Name(b"Identity"));
}
// Extract the widths of all glyphs.
let mut widths = vec![];
for gid in std::iter::once(0).chain(glyph_set.keys().copied()) {
let width = ttf.glyph_hor_advance(GlyphId(gid)).unwrap_or(0);
let units = font.to_em(width).to_font_units();
let cid = glyph_cid(font, gid);
if usize::from(cid) >= widths.len() {
widths.resize(usize::from(cid) + 1, 0.0);
widths[usize::from(cid)] = units;
}
}
// Write all non-zero glyph widths.
let mut first = 0;
let mut width_writer = cid.widths();
for (w, group) in widths.group_by_key(|&w| w) {
let end = first + group.len();
if w != 0.0 {
let last = end - 1;
width_writer.same(first as u16, last as u16, w);
}
first = end;
}
width_writer.finish();
cid.finish();
// Write the /ToUnicode character map, which maps glyph ids back to
// unicode codepoints to enable copying out of the PDF.
let cmap = create_cmap(font, glyph_set);
chunk.cmap(cmap_ref, &cmap.finish());
// Subset and write the font's bytes.
let glyphs: Vec<_> = glyph_set.keys().copied().collect();
let data = subset_font(font, &glyphs);
let mut stream = chunk.stream(data_ref, &data);
stream.filter(Filter::FlateDecode);
if is_cff {
stream.pair(Name(b"Subtype"), Name(b"CIDFontType0C"));
}
stream.finish();
let mut font_descriptor =
write_font_descriptor(&mut chunk, descriptor_ref, font, &base_font);
if is_cff {
font_descriptor.font_file3(data_ref);
} else {
font_descriptor.font_file2(data_ref);
}
}
});
(chunk, out)
}
/// Writes a FontDescriptor dictionary.
pub fn write_font_descriptor<'a>(
pdf: &'a mut Chunk,
descriptor_ref: Ref,
font: &'a Font,
base_font: &EcoString,
) -> FontDescriptor<'a> {
let ttf = font.ttf();
let metrics = font.metrics();
let postscript_name = font
.find_name(name_id::POST_SCRIPT_NAME)
.unwrap_or_else(|| "unknown".to_string());
let mut flags = FontFlags::empty();
flags.set(FontFlags::SERIF, postscript_name.contains("Serif"));
flags.set(FontFlags::FIXED_PITCH, ttf.is_monospaced());
flags.set(FontFlags::ITALIC, ttf.is_italic());
flags.insert(FontFlags::SYMBOLIC);
flags.insert(FontFlags::SMALL_CAP);
let global_bbox = ttf.global_bounding_box();
let bbox = Rect::new(
font.to_em(global_bbox.x_min).to_font_units(),
font.to_em(global_bbox.y_min).to_font_units(),
font.to_em(global_bbox.x_max).to_font_units(),
font.to_em(global_bbox.y_max).to_font_units(),
);
let italic_angle = ttf.italic_angle().unwrap_or(0.0);
let ascender = metrics.ascender.to_font_units();
let descender = metrics.descender.to_font_units();
let cap_height = metrics.cap_height.to_font_units();
let stem_v = 10.0 + 0.244 * (f32::from(ttf.weight().to_number()) - 50.0);
// Write the font descriptor (contains metrics about the font).
let mut font_descriptor = pdf.font_descriptor(descriptor_ref);
font_descriptor
.name(Name(base_font.as_bytes()))
.flags(flags)
.bbox(bbox)
.italic_angle(italic_angle)
.ascent(ascender)
.descent(descender)
.cap_height(cap_height)
.stem_v(stem_v);
font_descriptor
}
/// Subset a font to the given glyphs.
///
/// - For a font with TrueType outlines, this returns the whole OpenType font.
/// - For a font with CFF outlines, this returns just the CFF font program.
#[comemo::memoize]
#[typst_macros::time(name = "subset font")]
fn subset_font(font: &Font, glyphs: &[u16]) -> Arc<Vec<u8>> {
let data = font.data();
let profile = subsetter::Profile::pdf(glyphs);
let subsetted = subsetter::subset(data, font.index(), profile);
let mut data = subsetted.as_deref().unwrap_or(data);
// Extract the standalone CFF font program if applicable.
let raw = ttf_parser::RawFace::parse(data, 0).unwrap();
if let Some(cff) = raw.table(CFF) {
data = cff;
}
Arc::new(deflate(data))
}
/// Produce a unique 6 letter tag for a glyph set.
pub(crate) fn subset_tag<T: Hash>(glyphs: &T) -> EcoString {
const LEN: usize = 6;
const BASE: u128 = 26;
let mut hash = typst::utils::hash128(&glyphs);
let mut letter = [b'A'; LEN];
for l in letter.iter_mut() {
*l = b'A' + (hash % BASE) as u8;
hash /= BASE;
}
std::str::from_utf8(&letter).unwrap().into()
}
/// For glyphs that have codepoints mapping to them in the font's cmap table, we
/// prefer them over pre-existing text mappings from the document. Only things
/// that don't have a corresponding codepoint (or only a private-use one) like
/// the "Th" in Linux Libertine get the text of their first occurrences in the
/// document instead.
///
/// This function replaces as much copepoints from the document with ones from
/// the cmap table as possible.
pub fn improve_glyph_sets(glyph_sets: &mut HashMap<Font, BTreeMap<u16, EcoString>>) {
for (font, glyph_set) in glyph_sets {
let ttf = font.ttf();
for subtable in ttf.tables().cmap.into_iter().flat_map(|table| table.subtables) {
if !subtable.is_unicode() {
continue;
}
subtable.codepoints(|n| {
let Some(c) = std::char::from_u32(n) else { return };
if c.general_category() == GeneralCategory::PrivateUse {
return;
}
let Some(GlyphId(g)) = ttf.glyph_index(c) else { return };
if glyph_set.contains_key(&g) {
glyph_set.insert(g, c.into());
}
});
}
}
}
/// Create a /ToUnicode CMap.
fn create_cmap(font: &Font, glyph_set: &BTreeMap<u16, EcoString>) -> UnicodeCmap {
// Produce a reverse mapping from glyphs' CIDs to unicode strings.
let mut cmap = UnicodeCmap::new(CMAP_NAME, SYSTEM_INFO);
for (&g, text) in glyph_set.iter() {
if !text.is_empty() {
cmap.pair_with_multiple(glyph_cid(font, g), text.chars());
}
}
cmap
}
/// Get the CID for a glyph id.
///
/// When writing text into a PDF, we have to specify CIDs (character ids) not
/// GIDs (glyph IDs).
///
/// Most of the time, the mapping between these two is an identity mapping. In
/// particular, for TrueType fonts, the mapping is an identity mapping because
/// of this line above:
/// ```ignore
/// cid.cid_to_gid_map_predefined(Name(b"Identity"));
/// ```
///
/// However, CID-keyed CFF fonts may have a non-identity mapping defined in
/// their charset. For those, we must map the glyph IDs in a `TextItem` to CIDs.
/// The font defines the map through its charset. The charset usually maps
/// glyphs to SIDs (string ids) specifying the glyph's name. Not for CID-keyed
/// fonts though! For these, the SIDs are CIDs in disguise. Relevant quote from
/// the CFF spec:
///
/// > The charset data, although in the same format as non-CIDFonts, will
/// > represent CIDs rather than SIDs, [...]
///
/// This function performs the mapping from glyph ID to CID. It also works for
/// non CID-keyed fonts. Then, it will simply return the glyph ID.
pub(super) fn glyph_cid(font: &Font, glyph_id: u16) -> u16 {
font.ttf()
.tables()
.cff
.and_then(|cff| cff.glyph_cid(ttf_parser::GlyphId(glyph_id)))
.unwrap_or(glyph_id)
}
|
