A very short and simplified introduction
Fonts in PDF are PDF objects -
Font dictionaries, containing numerous parameters and sub-dictionaries, necessary to select glyphs, show them and translate character codes to logical (Unicode) representation for content extraction. Fonts in layman terms -- as we see them as *.ttf or *.pfb files -- are called font programs, either embedded or external, and are referred to by one of sub-dictionaries of
Fonts are divided into two groups:
- Simple fonts (Type1, Type3 or TrueType), in which glyphs are selected by single-byte character codes obtained from a string that is shown by the text-showing operators. The mapping from codes to glyphs is called the font’s encoding, it can be either built-in into font program or defined by
Font object (by predefined name or explicitly) or, under special circumstances, constructed according to defined rules by viewer application.
The file in question doesn't contain simple fonts, and we won't discuss them any further -- but, note, over-simplistic description doesn't even start to reflect any of real-life complexity.
- Composite fonts (Type0), used to show text in which character codes can have variable length (up to 4 bytes), and which, therefore, isn't restricted to 256 code-points. Type0 font always has one descendant which is a font-like object called
CIDFont, and, similar to encoding for simple fonts, a
CMap object, that maps character codes to character selectors, which, in PDF, are always
CIDs -- integers up to 65536.
Now, character selector (
CID) is not, in general, directly used to select glyphs from font program. For
CIDFontType2 type, its dictionary contains
CIDToGIDMap entry, that, obviously, maps
CID to glyph identifiers. Those
GIDs are, at last, used to select glyphs from embedded font program (which, for
CIDFontType2 font, is a TrueType font program (do not confuse with
Font object of TrueType
Font object can have
ToUnicode resource, that maps CIDs to Unicode values for indexing, searching and extraction. It's called
ToUnicode Cmap (as it follows similar syntax), but it should not to be confused with
CMap object, mentioned above.
In what I call a simple case (and, I think, sensible decision),
CMap is predefined Identity-H name,
CIDToGIDMap is a predefined Identity name, and, therefore, character codes extracted from a string (argument to text showing operator) are always 2-byte numbers that, effectively, directly select glyphs from embedded TrueType program. From my experience, it's most common scenario, and as it appears, that's the case, against which common software is tested.
But, it's not the case with file in question.
(The end of a short and simplified introduction)
In our file, text showing operator, effectively, gets this string:
0x000a 0x000a 0x000a 0x20 0x0020 0x0020 0x0020 0x20 0x0025 0x0025 0x0025
Of course there are no 'groups', they are here because I made them, based on
CMap that contains 2 ranges:
To make a long story short, if we look up character codes in
CMap and get CIDs, then look up CIDs in
CIDToGIDMap and get GIDs, then look up GIDs in embedded David-Bold font and get Unicode values, here's the table
Code CID GID Unicode Name
0x000a 10 180 05EA tav
0x0020 32 159 05D5 vav
0x0025 37 154 05D0 alef
0x20 228 03 0020 space
Now we have enough information to speculate, what confuses viewer applications
In my first attempt, I suggested it's
32 code (and
CID) that's used for non-space character (see comment above). This assumption was based on a case, several years ago, when (older version of) Acrobat didn't show character with
0x20 code, when it's at the end of a string -- assuming it to be
space, when in fact, according to encoding vector (of a simple font), it was another character.
I changed this:
0x0004 in content stream;
- bytes 08 and 09 in
CIDToGIDMap to GID=159;
- value in
Widths array of CID=4 to 'vav' width;
ToUnicode cmap was adjusted accordingly.
- (+ later I tried to remove
<0020> 32 string from
CMAP - not reflected in a file, linked in comment)
Well, it did help, but unfortunately, some of viewers still rejected to comply to specification.
Then I thought, that maybe variable character code width was the issue.
I returned to the original file and changed this:
0x00e4 in content stream;
<20> 228 to
<00e4> 228 in
<20> <20> in
<20> <20> in
ToUnicode Cmap deleted.
This file appears to open perfectly in all viewers, mentioned in original question and comments below. Miraculously,
0x0020 code and
CID do not interfere.
The conclusion, I think, can be this:
Given current state of affairs, PDF-creators are NOT advised to mix single and double byte codes in font encoding (