ed91dc314e
This lets us load a glyph at e.g. 12 pixels per em. Change-Id: I048b3db89af8670782953a8361afe0e6373df9b0 Reviewed-on: https://go-review.googlesource.com/37175 Reviewed-by: David Crawshaw <crawshaw@golang.org>
866 lines
23 KiB
Go
866 lines
23 KiB
Go
// Copyright 2016 The Go Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style
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// license that can be found in the LICENSE file.
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package sfnt
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// Compact Font Format (CFF) fonts are written in PostScript, a stack-based
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// programming language.
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//
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// A fundamental concept is a DICT, or a key-value map, expressed in reverse
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// Polish notation. For example, this sequence of operations:
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// - push the number 379
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// - version operator
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// - push the number 392
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// - Notice operator
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// - etc
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// - push the number 100
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// - push the number 0
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// - push the number 500
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// - push the number 800
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// - FontBBox operator
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// - etc
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// defines a DICT that maps "version" to the String ID (SID) 379, "Notice" to
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// the SID 392, "FontBBox" to the four numbers [100, 0, 500, 800], etc.
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//
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// The first 391 String IDs (starting at 0) are predefined as per the CFF spec
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// Appendix A, in 5176.CFF.pdf referenced below. For example, 379 means
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// "001.000". String ID 392 is not predefined, and is mapped by a separate
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// structure, the "String INDEX", inside the CFF data. (String ID 391 is also
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// not predefined. Specifically for ../testdata/CFFTest.otf, 391 means
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// "uni4E2D", as this font contains a glyph for U+4E2D).
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//
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// The actual glyph vectors are similarly encoded (in PostScript), in a format
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// called Type 2 Charstrings. The wire encoding is similar to but not exactly
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// the same as CFF's. For example, the byte 0x05 means FontBBox for CFF DICTs,
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// but means rlineto (relative line-to) for Type 2 Charstrings. See
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// 5176.CFF.pdf Appendix H and 5177.Type2.pdf Appendix A in the PDF files
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// referenced below.
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//
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// CFF is a stand-alone format, but CFF as used in SFNT fonts have further
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// restrictions. For example, a stand-alone CFF can contain multiple fonts, but
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// https://www.microsoft.com/typography/OTSPEC/cff.htm says that "The Name
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// INDEX in the CFF must contain only one entry; that is, there must be only
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// one font in the CFF FontSet".
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//
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// The relevant specifications are:
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// - http://wwwimages.adobe.com/content/dam/Adobe/en/devnet/font/pdfs/5176.CFF.pdf
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// - http://wwwimages.adobe.com/content/dam/Adobe/en/devnet/font/pdfs/5177.Type2.pdf
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import (
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"fmt"
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"math"
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"strconv"
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"golang.org/x/image/math/fixed"
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)
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const (
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// psStackSize is the stack size for a PostScript interpreter. 5176.CFF.pdf
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// section 4 "DICT Data" says that "An operator may be preceded by up to a
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// maximum of 48 operands". Similarly, 5177.Type2.pdf Appendix B "Type 2
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// Charstring Implementation Limits" says that "Argument stack 48".
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psStackSize = 48
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)
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func bigEndian(b []byte) uint32 {
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switch len(b) {
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case 1:
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return uint32(b[0])
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case 2:
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return uint32(b[0])<<8 | uint32(b[1])
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case 3:
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return uint32(b[0])<<16 | uint32(b[1])<<8 | uint32(b[2])
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case 4:
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return uint32(b[0])<<24 | uint32(b[1])<<16 | uint32(b[2])<<8 | uint32(b[3])
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}
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panic("unreachable")
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}
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// cffParser parses the CFF table from an SFNT font.
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type cffParser struct {
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src *source
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base int
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offset int
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end int
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err error
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buf []byte
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locBuf [2]uint32
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psi psInterpreter
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}
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func (p *cffParser) parse() (locations []uint32, err error) {
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// Parse header.
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{
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if !p.read(4) {
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return nil, p.err
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}
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if p.buf[0] != 1 || p.buf[1] != 0 || p.buf[2] != 4 {
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return nil, errUnsupportedCFFVersion
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}
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}
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// Parse Name INDEX.
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{
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count, offSize, ok := p.parseIndexHeader()
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if !ok {
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return nil, p.err
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}
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// https://www.microsoft.com/typography/OTSPEC/cff.htm says that "The
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// Name INDEX in the CFF must contain only one entry".
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if count != 1 {
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return nil, errInvalidCFFTable
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}
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if !p.parseIndexLocations(p.locBuf[:2], count, offSize) {
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return nil, p.err
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}
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p.offset = int(p.locBuf[1])
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}
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// Parse Top DICT INDEX.
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{
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count, offSize, ok := p.parseIndexHeader()
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if !ok {
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return nil, p.err
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}
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// 5176.CFF.pdf section 8 "Top DICT INDEX" says that the count here
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// should match the count of the Name INDEX, which is 1.
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if count != 1 {
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return nil, errInvalidCFFTable
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}
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if !p.parseIndexLocations(p.locBuf[:2], count, offSize) {
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return nil, p.err
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}
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if !p.read(int(p.locBuf[1] - p.locBuf[0])) {
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return nil, p.err
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}
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p.psi.topDict.initialize()
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if p.err = p.psi.run(psContextTopDict, p.buf); p.err != nil {
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return nil, p.err
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}
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}
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// Parse the CharStrings INDEX, whose location was found in the Top DICT.
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if p.psi.topDict.charStrings <= 0 || int32(p.end-p.base) < p.psi.topDict.charStrings {
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return nil, errInvalidCFFTable
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}
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p.offset = p.base + int(p.psi.topDict.charStrings)
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count, offSize, ok := p.parseIndexHeader()
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if !ok {
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return nil, p.err
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}
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if count == 0 {
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return nil, errInvalidCFFTable
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}
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locations = make([]uint32, count+1)
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if !p.parseIndexLocations(locations, count, offSize) {
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return nil, p.err
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}
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return locations, nil
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}
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// read sets p.buf to view the n bytes from p.offset to p.offset+n. It also
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// advances p.offset by n.
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//
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// As per the source.view method, the caller should not modify the contents of
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// p.buf after read returns, other than by calling read again.
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//
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// The caller should also avoid modifying the pointer / length / capacity of
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// the p.buf slice, not just avoid modifying the slice's contents, in order to
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// maximize the opportunity to re-use p.buf's allocated memory when viewing the
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// underlying source data for subsequent read calls.
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func (p *cffParser) read(n int) (ok bool) {
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if p.end-p.offset < n {
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p.err = errInvalidCFFTable
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return false
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}
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p.buf, p.err = p.src.view(p.buf, p.offset, n)
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p.offset += n
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return p.err == nil
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}
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func (p *cffParser) parseIndexHeader() (count, offSize int32, ok bool) {
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if !p.read(2) {
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return 0, 0, false
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}
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count = int32(u16(p.buf[:2]))
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// 5176.CFF.pdf section 5 "INDEX Data" says that "An empty INDEX is
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// represented by a count field with a 0 value and no additional fields.
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// Thus, the total size of an empty INDEX is 2 bytes".
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if count == 0 {
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return count, 0, true
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}
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if !p.read(1) {
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return 0, 0, false
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}
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offSize = int32(p.buf[0])
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if offSize < 1 || 4 < offSize {
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p.err = errInvalidCFFTable
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return 0, 0, false
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}
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return count, offSize, true
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}
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func (p *cffParser) parseIndexLocations(dst []uint32, count, offSize int32) (ok bool) {
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if count == 0 {
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return true
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}
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if len(dst) != int(count+1) {
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panic("unreachable")
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}
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if !p.read(len(dst) * int(offSize)) {
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return false
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}
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buf, prev := p.buf, uint32(0)
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for i := range dst {
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loc := bigEndian(buf[:offSize])
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buf = buf[offSize:]
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// Locations are off by 1 byte. 5176.CFF.pdf section 5 "INDEX Data"
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// says that "Offsets in the offset array are relative to the byte that
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// precedes the object data... This ensures that every object has a
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// corresponding offset which is always nonzero".
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if loc == 0 {
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p.err = errInvalidCFFTable
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return false
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}
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loc--
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// In the same paragraph, "Therefore the first element of the offset
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// array is always 1" before correcting for the off-by-1.
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if i == 0 {
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if loc != 0 {
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p.err = errInvalidCFFTable
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break
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}
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} else if loc <= prev { // Check that locations are increasing.
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p.err = errInvalidCFFTable
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break
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}
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// Check that locations are in bounds.
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if uint32(p.end-p.offset) < loc {
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p.err = errInvalidCFFTable
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break
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}
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dst[i] = uint32(p.offset) + loc
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prev = loc
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}
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return p.err == nil
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}
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type psContext uint32
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const (
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psContextTopDict psContext = iota
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psContextType2Charstring
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)
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// psTopDictData contains fields specific to the Top DICT context.
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type psTopDictData struct {
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charStrings int32
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}
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func (d *psTopDictData) initialize() {
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*d = psTopDictData{}
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}
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// psType2CharstringsData contains fields specific to the Type 2 Charstrings
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// context.
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type psType2CharstringsData struct {
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segments []Segment
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x, y int32
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hintBits int32
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seenWidth bool
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}
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func (d *psType2CharstringsData) initialize(segments []Segment) {
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*d = psType2CharstringsData{
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segments: segments,
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}
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}
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// psInterpreter is a PostScript interpreter.
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type psInterpreter struct {
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ctx psContext
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instructions []byte
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stack struct {
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a [psStackSize]int32
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top int32
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}
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parseNumberBuf [maxRealNumberStrLen]byte
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topDict psTopDictData
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type2Charstrings psType2CharstringsData
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}
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func (p *psInterpreter) run(ctx psContext, instructions []byte) error {
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p.ctx = ctx
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p.instructions = instructions
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p.stack.top = 0
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loop:
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for len(p.instructions) > 0 {
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// Push a numeric operand on the stack, if applicable.
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if hasResult, err := p.parseNumber(); hasResult {
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if err != nil {
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return err
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}
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continue
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}
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// Otherwise, execute an operator.
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b := p.instructions[0]
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p.instructions = p.instructions[1:]
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for escaped, ops := false, psOperators[ctx][0]; ; {
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if b == escapeByte && !escaped {
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if len(p.instructions) <= 0 {
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return errInvalidCFFTable
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}
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b = p.instructions[0]
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p.instructions = p.instructions[1:]
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escaped = true
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ops = psOperators[ctx][1]
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continue
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}
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if int(b) < len(ops) {
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if op := ops[b]; op.name != "" {
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if p.stack.top < op.numPop {
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return errInvalidCFFTable
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}
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if op.run != nil {
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if err := op.run(p); err != nil {
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return err
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}
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}
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if op.numPop < 0 {
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p.stack.top = 0
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} else {
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p.stack.top -= op.numPop
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}
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continue loop
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}
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}
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if escaped {
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return fmt.Errorf("sfnt: unrecognized CFF 2-byte operator (12 %d)", b)
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} else {
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return fmt.Errorf("sfnt: unrecognized CFF 1-byte operator (%d)", b)
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}
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}
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}
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return nil
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}
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// See 5176.CFF.pdf section 4 "DICT Data".
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func (p *psInterpreter) parseNumber() (hasResult bool, err error) {
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number := int32(0)
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switch b := p.instructions[0]; {
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case b == 28:
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if len(p.instructions) < 3 {
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return true, errInvalidCFFTable
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}
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number, hasResult = int32(int16(u16(p.instructions[1:]))), true
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p.instructions = p.instructions[3:]
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case b == 29 && p.ctx == psContextTopDict:
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if len(p.instructions) < 5 {
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return true, errInvalidCFFTable
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}
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number, hasResult = int32(u32(p.instructions[1:])), true
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p.instructions = p.instructions[5:]
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case b == 30 && p.ctx == psContextTopDict:
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// Parse a real number. This isn't listed in 5176.CFF.pdf Table 3
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// "Operand Encoding" but that table lists integer encodings. Further
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// down the page it says "A real number operand is provided in addition
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// to integer operands. This operand begins with a byte value of 30
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// followed by a variable-length sequence of bytes."
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s := p.parseNumberBuf[:0]
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p.instructions = p.instructions[1:]
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loop:
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for {
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if len(p.instructions) == 0 {
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return true, errInvalidCFFTable
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}
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b := p.instructions[0]
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p.instructions = p.instructions[1:]
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// Process b's two nibbles, high then low.
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for i := 0; i < 2; i++ {
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nib := b >> 4
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b = b << 4
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if nib == 0x0f {
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f, err := strconv.ParseFloat(string(s), 32)
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if err != nil {
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return true, errInvalidCFFTable
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}
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number, hasResult = int32(math.Float32bits(float32(f))), true
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break loop
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}
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if nib == 0x0d {
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return true, errInvalidCFFTable
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}
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if len(s)+maxNibbleDefsLength > len(p.parseNumberBuf) {
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return true, errUnsupportedRealNumberEncoding
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}
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s = append(s, nibbleDefs[nib]...)
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}
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}
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case b < 32:
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// No-op.
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case b < 247:
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p.instructions = p.instructions[1:]
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number, hasResult = int32(b)-139, true
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case b < 251:
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if len(p.instructions) < 2 {
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return true, errInvalidCFFTable
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}
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b1 := p.instructions[1]
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p.instructions = p.instructions[2:]
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number, hasResult = +int32(b-247)*256+int32(b1)+108, true
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case b < 255:
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if len(p.instructions) < 2 {
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return true, errInvalidCFFTable
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}
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b1 := p.instructions[1]
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p.instructions = p.instructions[2:]
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number, hasResult = -int32(b-251)*256-int32(b1)-108, true
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case b == 255 && p.ctx == psContextType2Charstring:
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if len(p.instructions) < 5 {
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return true, errInvalidCFFTable
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}
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number, hasResult = int32(u32(p.instructions[1:])), true
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p.instructions = p.instructions[5:]
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}
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if hasResult {
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if p.stack.top == psStackSize {
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return true, errInvalidCFFTable
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}
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p.stack.a[p.stack.top] = number
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p.stack.top++
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}
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return hasResult, nil
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}
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const maxNibbleDefsLength = len("E-")
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// nibbleDefs encodes 5176.CFF.pdf Table 5 "Nibble Definitions".
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var nibbleDefs = [16]string{
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0x00: "0",
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0x01: "1",
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0x02: "2",
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0x03: "3",
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0x04: "4",
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0x05: "5",
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0x06: "6",
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0x07: "7",
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0x08: "8",
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0x09: "9",
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0x0a: ".",
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0x0b: "E",
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0x0c: "E-",
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0x0d: "",
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0x0e: "-",
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0x0f: "",
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}
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type psOperator struct {
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// numPop is the number of stack values to pop. -1 means "array" and -2
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// means "delta" as per 5176.CFF.pdf Table 6 "Operand Types".
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numPop int32
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// name is the operator name. An empty name (i.e. the zero value for the
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// struct overall) means an unrecognized 1-byte operator.
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name string
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// run is the function that implements the operator. Nil means that we
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// ignore the operator, other than popping its arguments off the stack.
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run func(*psInterpreter) error
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}
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// psOperators holds the 1-byte and 2-byte operators for PostScript interpreter
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// contexts.
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var psOperators = [...][2][]psOperator{
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// The Top DICT operators are defined by 5176.CFF.pdf Table 9 "Top DICT
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// Operator Entries" and Table 10 "CIDFont Operator Extensions".
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psContextTopDict: {{
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// 1-byte operators.
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0: {+1, "version", nil},
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1: {+1, "Notice", nil},
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2: {+1, "FullName", nil},
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3: {+1, "FamilyName", nil},
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4: {+1, "Weight", nil},
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5: {-1, "FontBBox", nil},
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13: {+1, "UniqueID", nil},
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14: {-1, "XUID", nil},
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15: {+1, "charset", nil},
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16: {+1, "Encoding", nil},
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17: {+1, "CharStrings", func(p *psInterpreter) error {
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p.topDict.charStrings = p.stack.a[p.stack.top-1]
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return nil
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}},
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|
18: {+2, "Private", nil},
|
|
}, {
|
|
// 2-byte operators. The first byte is the escape byte.
|
|
0: {+1, "Copyright", nil},
|
|
1: {+1, "isFixedPitch", nil},
|
|
2: {+1, "ItalicAngle", nil},
|
|
3: {+1, "UnderlinePosition", nil},
|
|
4: {+1, "UnderlineThickness", nil},
|
|
5: {+1, "PaintType", nil},
|
|
6: {+1, "CharstringType", nil},
|
|
7: {-1, "FontMatrix", nil},
|
|
8: {+1, "StrokeWidth", nil},
|
|
20: {+1, "SyntheticBase", nil},
|
|
21: {+1, "PostScript", nil},
|
|
22: {+1, "BaseFontName", nil},
|
|
23: {-2, "BaseFontBlend", nil},
|
|
30: {+3, "ROS", nil},
|
|
31: {+1, "CIDFontVersion", nil},
|
|
32: {+1, "CIDFontRevision", nil},
|
|
33: {+1, "CIDFontType", nil},
|
|
34: {+1, "CIDCount", nil},
|
|
35: {+1, "UIDBase", nil},
|
|
36: {+1, "FDArray", nil},
|
|
37: {+1, "FDSelect", nil},
|
|
38: {+1, "FontName", nil},
|
|
}},
|
|
|
|
// The Type 2 Charstring operators are defined by 5177.Type2.pdf Appendix A
|
|
// "Type 2 Charstring Command Codes".
|
|
psContextType2Charstring: {{
|
|
// 1-byte operators.
|
|
0: {}, // Reserved.
|
|
1: {-1, "hstem", t2CStem},
|
|
2: {}, // Reserved.
|
|
3: {-1, "vstem", t2CStem},
|
|
4: {-1, "vmoveto", t2CVmoveto},
|
|
5: {-1, "rlineto", t2CRlineto},
|
|
6: {-1, "hlineto", t2CHlineto},
|
|
7: {-1, "vlineto", t2CVlineto},
|
|
8: {-1, "rrcurveto", t2CRrcurveto},
|
|
9: {}, // Reserved.
|
|
10: {}, // callsubr.
|
|
11: {}, // return.
|
|
12: {}, // escape.
|
|
13: {}, // Reserved.
|
|
14: {-1, "endchar", t2CEndchar},
|
|
15: {}, // Reserved.
|
|
16: {}, // Reserved.
|
|
17: {}, // Reserved.
|
|
18: {-1, "hstemhm", t2CStem},
|
|
19: {-1, "hintmask", t2CMask},
|
|
20: {-1, "cntrmask", t2CMask},
|
|
21: {-1, "rmoveto", t2CRmoveto},
|
|
22: {-1, "hmoveto", t2CHmoveto},
|
|
23: {-1, "vstemhm", t2CStem},
|
|
24: {}, // rcurveline.
|
|
25: {}, // rlinecurve.
|
|
26: {}, // vvcurveto.
|
|
27: {}, // hhcurveto.
|
|
28: {}, // shortint.
|
|
29: {}, // callgsubr.
|
|
30: {-1, "vhcurveto", t2CVhcurveto},
|
|
31: {-1, "hvcurveto", t2CHvcurveto},
|
|
}, {
|
|
// 2-byte operators. The first byte is the escape byte.
|
|
0: {}, // Reserved.
|
|
// TODO: more operators.
|
|
}},
|
|
}
|
|
|
|
// 5176.CFF.pdf section 4 "DICT Data" says that "Two-byte operators have an
|
|
// initial escape byte of 12".
|
|
const escapeByte = 12
|
|
|
|
// t2CReadWidth reads the optional width adjustment. If present, it is on the
|
|
// bottom of the stack.
|
|
//
|
|
// 5177.Type2.pdf page 16 Note 4 says: "The first stack-clearing operator,
|
|
// which must be one of hstem, hstemhm, vstem, vstemhm, cntrmask, hintmask,
|
|
// hmoveto, vmoveto, rmoveto, or endchar, takes an additional argument — the
|
|
// width... which may be expressed as zero or one numeric argument."
|
|
func t2CReadWidth(p *psInterpreter, nArgs int32) {
|
|
if p.type2Charstrings.seenWidth {
|
|
return
|
|
}
|
|
p.type2Charstrings.seenWidth = true
|
|
switch nArgs {
|
|
case 0:
|
|
if p.stack.top != 1 {
|
|
return
|
|
}
|
|
case 1:
|
|
if p.stack.top <= 1 {
|
|
return
|
|
}
|
|
default:
|
|
if p.stack.top%nArgs != 1 {
|
|
return
|
|
}
|
|
}
|
|
// When parsing a standalone CFF, we'd save the value of p.stack.a[0] here
|
|
// as it defines the glyph's width (horizontal advance). Specifically, if
|
|
// present, it is a delta to the font-global nominalWidthX value found in
|
|
// the Private DICT. If absent, the glyph's width is the defaultWidthX
|
|
// value in that dict. See 5176.CFF.pdf section 15 "Private DICT Data".
|
|
//
|
|
// For a CFF embedded in an SFNT font (i.e. an OpenType font), glyph widths
|
|
// are already stored in the hmtx table, separate to the CFF table, and it
|
|
// is simpler to parse that table for all OpenType fonts (PostScript and
|
|
// TrueType). We therefore ignore the width value here, and just remove it
|
|
// from the bottom of the stack.
|
|
copy(p.stack.a[:p.stack.top-1], p.stack.a[1:p.stack.top])
|
|
p.stack.top--
|
|
}
|
|
|
|
func t2CStem(p *psInterpreter) error {
|
|
t2CReadWidth(p, 2)
|
|
if p.stack.top%2 != 0 {
|
|
return errInvalidCFFTable
|
|
}
|
|
// We update the number of hintBits need to parse hintmask and cntrmask
|
|
// instructions, but this Type 2 Charstring implementation otherwise
|
|
// ignores the stem hints.
|
|
p.type2Charstrings.hintBits += p.stack.top / 2
|
|
if p.type2Charstrings.hintBits > maxHintBits {
|
|
return errUnsupportedNumberOfHints
|
|
}
|
|
return nil
|
|
}
|
|
|
|
func t2CMask(p *psInterpreter) error {
|
|
hintBytes := (p.type2Charstrings.hintBits + 7) / 8
|
|
t2CReadWidth(p, hintBytes)
|
|
if len(p.instructions) < int(hintBytes) {
|
|
return errInvalidCFFTable
|
|
}
|
|
p.instructions = p.instructions[hintBytes:]
|
|
return nil
|
|
}
|
|
|
|
func t2CAppendMoveto(p *psInterpreter) {
|
|
p.type2Charstrings.segments = append(p.type2Charstrings.segments, Segment{
|
|
Op: SegmentOpMoveTo,
|
|
Args: [6]fixed.Int26_6{
|
|
0: fixed.Int26_6(p.type2Charstrings.x),
|
|
1: fixed.Int26_6(p.type2Charstrings.y),
|
|
},
|
|
})
|
|
}
|
|
|
|
func t2CAppendLineto(p *psInterpreter) {
|
|
p.type2Charstrings.segments = append(p.type2Charstrings.segments, Segment{
|
|
Op: SegmentOpLineTo,
|
|
Args: [6]fixed.Int26_6{
|
|
0: fixed.Int26_6(p.type2Charstrings.x),
|
|
1: fixed.Int26_6(p.type2Charstrings.y),
|
|
},
|
|
})
|
|
}
|
|
|
|
func t2CAppendCubeto(p *psInterpreter, dxa, dya, dxb, dyb, dxc, dyc int32) {
|
|
p.type2Charstrings.x += dxa
|
|
p.type2Charstrings.y += dya
|
|
xa := p.type2Charstrings.x
|
|
ya := p.type2Charstrings.y
|
|
p.type2Charstrings.x += dxb
|
|
p.type2Charstrings.y += dyb
|
|
xb := p.type2Charstrings.x
|
|
yb := p.type2Charstrings.y
|
|
p.type2Charstrings.x += dxc
|
|
p.type2Charstrings.y += dyc
|
|
xc := p.type2Charstrings.x
|
|
yc := p.type2Charstrings.y
|
|
p.type2Charstrings.segments = append(p.type2Charstrings.segments, Segment{
|
|
Op: SegmentOpCubeTo,
|
|
Args: [6]fixed.Int26_6{
|
|
0: fixed.Int26_6(xa),
|
|
1: fixed.Int26_6(ya),
|
|
2: fixed.Int26_6(xb),
|
|
3: fixed.Int26_6(yb),
|
|
4: fixed.Int26_6(xc),
|
|
5: fixed.Int26_6(yc),
|
|
},
|
|
})
|
|
}
|
|
|
|
func t2CHmoveto(p *psInterpreter) error {
|
|
t2CReadWidth(p, 1)
|
|
if p.stack.top < 1 {
|
|
return errInvalidCFFTable
|
|
}
|
|
for i := int32(0); i < p.stack.top; i++ {
|
|
p.type2Charstrings.x += p.stack.a[i]
|
|
}
|
|
t2CAppendMoveto(p)
|
|
return nil
|
|
}
|
|
|
|
func t2CVmoveto(p *psInterpreter) error {
|
|
t2CReadWidth(p, 1)
|
|
if p.stack.top < 1 {
|
|
return errInvalidCFFTable
|
|
}
|
|
for i := int32(0); i < p.stack.top; i++ {
|
|
p.type2Charstrings.y += p.stack.a[i]
|
|
}
|
|
t2CAppendMoveto(p)
|
|
return nil
|
|
}
|
|
|
|
func t2CRmoveto(p *psInterpreter) error {
|
|
t2CReadWidth(p, 2)
|
|
if p.stack.top < 2 || p.stack.top%2 != 0 {
|
|
return errInvalidCFFTable
|
|
}
|
|
for i := int32(0); i < p.stack.top; i += 2 {
|
|
p.type2Charstrings.x += p.stack.a[i+0]
|
|
p.type2Charstrings.y += p.stack.a[i+1]
|
|
}
|
|
t2CAppendMoveto(p)
|
|
return nil
|
|
}
|
|
|
|
func t2CHlineto(p *psInterpreter) error { return t2CLineto(p, false) }
|
|
func t2CVlineto(p *psInterpreter) error { return t2CLineto(p, true) }
|
|
|
|
func t2CLineto(p *psInterpreter, vertical bool) error {
|
|
if !p.type2Charstrings.seenWidth {
|
|
return errInvalidCFFTable
|
|
}
|
|
if p.stack.top < 1 {
|
|
return errInvalidCFFTable
|
|
}
|
|
for i := int32(0); i < p.stack.top; i, vertical = i+1, !vertical {
|
|
if vertical {
|
|
p.type2Charstrings.y += p.stack.a[i]
|
|
} else {
|
|
p.type2Charstrings.x += p.stack.a[i]
|
|
}
|
|
t2CAppendLineto(p)
|
|
}
|
|
return nil
|
|
}
|
|
|
|
func t2CRlineto(p *psInterpreter) error {
|
|
if !p.type2Charstrings.seenWidth {
|
|
return errInvalidCFFTable
|
|
}
|
|
if p.stack.top < 2 || p.stack.top%2 != 0 {
|
|
return errInvalidCFFTable
|
|
}
|
|
for i := int32(0); i < p.stack.top; i += 2 {
|
|
p.type2Charstrings.x += p.stack.a[i+0]
|
|
p.type2Charstrings.y += p.stack.a[i+1]
|
|
t2CAppendLineto(p)
|
|
}
|
|
return nil
|
|
}
|
|
|
|
// As per 5177.Type2.pdf section 4.1 "Path Construction Operators",
|
|
//
|
|
// hvcurveto is one of:
|
|
// - dx1 dx2 dy2 dy3 {dya dxb dyb dxc dxd dxe dye dyf}* dxf?
|
|
// - {dxa dxb dyb dyc dyd dxe dye dxf}+ dyf?
|
|
//
|
|
// vhcurveto is one of:
|
|
// - dy1 dx2 dy2 dx3 {dxa dxb dyb dyc dyd dxe dye dxf}* dyf?
|
|
// - {dya dxb dyb dxc dxd dxe dye dyf}+ dxf?
|
|
|
|
func t2CHvcurveto(p *psInterpreter) error { return t2CCurveto(p, false) }
|
|
func t2CVhcurveto(p *psInterpreter) error { return t2CCurveto(p, true) }
|
|
|
|
func t2CCurveto(p *psInterpreter, vertical bool) error {
|
|
if !p.type2Charstrings.seenWidth || p.stack.top < 4 {
|
|
return errInvalidCFFTable
|
|
}
|
|
for i := int32(0); i != p.stack.top; vertical = !vertical {
|
|
if vertical {
|
|
i = t2CVcurveto(p, i)
|
|
} else {
|
|
i = t2CHcurveto(p, i)
|
|
}
|
|
if i < 0 {
|
|
return errInvalidCFFTable
|
|
}
|
|
}
|
|
return nil
|
|
}
|
|
|
|
func t2CHcurveto(p *psInterpreter, i int32) (j int32) {
|
|
if i+4 > p.stack.top {
|
|
return -1
|
|
}
|
|
dxa := p.stack.a[i+0]
|
|
dxb := p.stack.a[i+1]
|
|
dyb := p.stack.a[i+2]
|
|
dyc := p.stack.a[i+3]
|
|
dxc := int32(0)
|
|
i += 4
|
|
if i+1 == p.stack.top {
|
|
dxc = p.stack.a[i]
|
|
i++
|
|
}
|
|
t2CAppendCubeto(p, dxa, 0, dxb, dyb, dxc, dyc)
|
|
return i
|
|
}
|
|
|
|
func t2CVcurveto(p *psInterpreter, i int32) (j int32) {
|
|
if i+4 > p.stack.top {
|
|
return -1
|
|
}
|
|
dya := p.stack.a[i+0]
|
|
dxb := p.stack.a[i+1]
|
|
dyb := p.stack.a[i+2]
|
|
dxc := p.stack.a[i+3]
|
|
dyc := int32(0)
|
|
i += 4
|
|
if i+1 == p.stack.top {
|
|
dyc = p.stack.a[i]
|
|
i++
|
|
}
|
|
t2CAppendCubeto(p, 0, dya, dxb, dyb, dxc, dyc)
|
|
return i
|
|
}
|
|
|
|
func t2CRrcurveto(p *psInterpreter) error {
|
|
if !p.type2Charstrings.seenWidth || p.stack.top < 6 || p.stack.top%6 != 0 {
|
|
return errInvalidCFFTable
|
|
}
|
|
for i := int32(0); i != p.stack.top; i += 6 {
|
|
t2CAppendCubeto(p,
|
|
p.stack.a[i+0],
|
|
p.stack.a[i+1],
|
|
p.stack.a[i+2],
|
|
p.stack.a[i+3],
|
|
p.stack.a[i+4],
|
|
p.stack.a[i+5],
|
|
)
|
|
}
|
|
return nil
|
|
}
|
|
|
|
func t2CEndchar(p *psInterpreter) error {
|
|
t2CReadWidth(p, 0)
|
|
if p.stack.top != 0 || len(p.instructions) != 0 {
|
|
if p.stack.top == 4 {
|
|
// TODO: process the implicit "seac" command as per 5177.Type2.pdf
|
|
// Appendix C "Compatibility and Deprecated Operators".
|
|
return errUnsupportedType2Charstring
|
|
}
|
|
return errInvalidCFFTable
|
|
}
|
|
return nil
|
|
}
|