Encoding varies based on the font type. Typically, there is a font resource that is defined as the current font and within that font dictionary is a reference to a base font and a means of describing the encoding (via the /Encoding key). If that key doesn't exist, the encoding will be "standard", but you can use other simple encodings such as /MacRoman and /WinAnsi for the value of the encoding, or you can specify a standard encoding and an encoding delta to show the differences.
Easy so far - as long as you're working with 8-bit characters. For many early apps, they would create a couple different fonts, one with say Roman encoding and another that maps roman characters to unavailable characters. In order to do that, your encoding delta would include references to the ligatures and other typically non-encoded symbols. This works great for Type 1 fonts, but is specifically contraindicated by the spec in the section on TrueType Fonts:
A nonsymbolic font should specify MacRomanEncoding or WinAnsiEncoding as the value of its Encoding entry, with no Differences array
This is vastly different when you want to use, say, Unicode. In which case you would be using a CID font (a font based on character IDs). In that case there is a procedure referenced by the font which is used to map from a character encoding in your string to a character ID in your font (and vice versa). I would strongly recommend that you read and fully understand section 9.7 in the PDF specification on Composite Fonts, which describes everything you need in order to encode UTF16BE into strings to get them to render properly in PDF. It is decidedly non-trivial in that there are a lot of details that if missed will result in a blank rendered page in Acrobat.
As a software engineer who professionally writes code that produces and consumes PDF, let me state that when I get tasked with having to put in special cases in my code to deal with non-spec compliant PDF, a little piece of me dies inside. Please, please, don't even think of releasing any documents you produce into the wild until they pass Preflight at the least. This is not the same as "Acrobat renders it so it must be OK." Let me give you an example - I've seen a number of files in the wild that include fonts that are missing the key elements of the FontDescriptor dictionary, including /Ascent, /Descent, /CapHeight, etc. These render in Acrobat, but are in violation of the spec since each of those is required. I know how Acrobat handles that - it comes with an enormous database of font metrics and looks up the value if it can't find it in the file (heck, it might even ignore the metrics in the file). I don't have that luxury, so I have to do a number of (potentially expensive/invalid) stop gap measures.
You might want to consider using a library to do this work for you - maybe iText which has a decent enough licensing scheme for education because, I get it, you're a student. There are some C based libraries too. Maybe you can figure a way to make GhostScript do your bidding.
If you are unwilling or unable to follow my advice with regards to cleaving to the specification or to use a library which ostensibly does so, please do me the favor of at least filling out the /Creator and /Producer strings in the Document Information Dictionary referenced by the trailer (see sections 14.3.3 and section 7.5.5). That way, when I have to parse/consume/manipulate your documents, I will have a way to directly cast aspersions on your parentage.
Let's go top down and start with the page object - I'm using output from my own library and am stripping out what I think you don't need:
1 0 obj <<
/Type /Page
/Parent 18 0 R
/Resources <<
/Font <<
/U0 13 0 R
>>
/ProcSet [ /PDF /Text ]
>>
/MediaBox [ 0 0 612 792 ]
/Contents 19 0 R
/Dur -1
>>
endobj
U0 is a reference to a font that will be used for unicode text.
The content stream is intended to print the following text: Greek: Γειά σου κόσμος.
BT /U0 24 Tf 72 670 Td
(\000G\000r\000e\000e\000k\000:\000 \003\223\003\265\003\271\003\254\000 \003\303\003\277\003\305\000 \003\272\003\314\003\303\003\274\003\277\003\302)
Tj ET
The font dictionary referenced looks like this:
13 0 obj <<
/BaseFont /DejaVuSansCondensed
/DescendantFonts [ 4 0 R ]
/ToUnicode 14 0 R
/Type /Font
/Subtype /Type0
/Encoding /Identity-H
>>
endobj
Which has the /ToUnicode entry points to a stream containing the following PostScript code:
/CIDInit /ProcSet findresource begin 12 dict begin begincmap /CIDSystemInfo << /Registry (Adobe) /Ordering (UCS) /Supplement 0 >> def /CMapName /Adobe-Identity-UCS def /CMapType 2 def 1 begincodespacerange <0000> <FFFF> endcodespacerange 1 beginbfrange <0000> <FFFF> <0000> endbfrange endcmap CMapName currentdict /CMap defineresource pop end end
which is defined by the CID font specification.
and the DescendantFonts array points to this object:
4 0 obj <<
/Subtype /CIDFontType2
/Type /Font
/BaseFont /DejaVuSansCondensed
/CIDSystemInfo 7 0 R
/FontDescriptor 8 0 R
/DW 1000
/W 9 0 R
/CIDToGIDMap 10 0 R
>>
The CIDToGIDMap is a compressed stream with the actual map, the CIDSystemInfo is <</Registry (Adobe) /Ordering (USC) /Supplement 0>> (it's a reference because I share it among all unicode fonts that I output. The FontDescriptor is a straight forward boiler plate, and the W array is derived from the font metrics.
With all this detail, are you understanding why I don't say lightly, "walk away before you pollute my environment any furhter"?
I'm really beginning to question the nature of the this assignment. Writing a simple PDF is one thing, but writing code that can handle full unicode in any arbitrary OpenType/TrueType font requires you to understand the CID spec and the TrueType spec (hint: I have a full TrueType parser that can extract all the metrics for any glyph in a font so that I can output the /W array).
If, however, you are required to only output to Type 1 fonts, well my friend, your life got a whole lot easier, because you would take your entire UTF8 stream, read it as unicode and for every unique character that comes in, you build a map from a unicode character to a glyph name and an internal character number by using this table. The internal character number essentially the unique index of the character that came in mod. So for example, if you have less than 257 unique characters on the page, you will have exactly one font that is encoded to map to the characters in the order that the arrived. If you had "abcba" for input, the output string in pdf would be (\000\001\002\001\000) and would map to a font with an encoding dictionary with a differences array that would be [0/a/b/c]. If you have n unique characters where n > 256, you're going to have (n / 256) + 1 fonts, each with encodings.
If your teacher/professor wants anything but Type 1 fonts in a short period of time, s/he has unrealistic expectations for the students and/or low expectations for the quality of output. You should ask whether your are required to handle CID fonts and if you are, then your professor is at the very least a sadist. It took me, a seasoned professional, about 4 days to write a TrueType parser for extracting widths. I had the advantage of (1) using a managed language (C#) which cut down on concerns that will be biting your ass in C and was also able to use reflection to automate parsing and (2) when I don't have interruptions, I write solid code about 10-20 times faster than a typical student, so my 32 hours would translate into 320 student hours, more or less (then again, my code has different constraints than yours - it has to consume any crap font it gets gracefully), so let's call it 200 or less if you're allowed to steal something like stb. That's just for getting one particular element in the font descriptor.
