INTRODUCTION ------------ This document describes the process of using the GNU Unifont utilities to create a font. The steps described in "Using Graphical Tools" are more or less the steps that I (Paul Hardy) followed to add thousands of glyphs to GNU Unifont, except that I didn't have the luxury of just typing "make" to make a new font while adding those glyphs. I streamlined the font build process after I was done drawing the Unicode 5.1 glyphs. I know that plain ASCII text is *so* last millennium, especially for a package related to Unicode. Yet ASCII can be read with anything; hence this format. DISCLAIMER: Donald Knuth warned in his Metafont book that if someone started designing type, they would never again be able to look at a page of text normally and just read its content. There is a point of no return beyond which a serious font designer begins looking at how individual letters in a font on a page are drawn, and how they might be improved. Be warned! -- Paul Hardy July 2008 with some revisions in 2013 UNICODE ------- Unicode is an international standard to encode all the world's scripts with one universal scheme. Unicode is the default encoding for web pages and is gaining popularity in many other applications. To learn more about Unicode, look at code charts, and see the latest developments, check out http://unicode.org GNU Unifont follows the Unicode encoding scheme. Unicode defines the numeric value of a character, but does not define one particular font. There can be (and are) many fonts that support a subset of Unifont characters. In 1998, Roman Czyborra observed that there was still no font, free or commercial, with complete Unicode coverage. He envisioned a low-quality bitmapped font as an easy way to produce a font that covered much of the Unicode standard. GNU UNIFONT STRUCTURE --------------------- GNU Unifont is a dual-width pixel font. Roman Czyborra began this font in 1998 with a goal of having one glyph rendered for each visible character in the Unicode Basic Multilingual Plane (Plane 0, the first 65,536 characters). His original writing on this is at http://czyborra.com/unifont/. (Note that the term "character" is used very loosely here for simplicity; the Unicode Standard has a stricter definition of what constitutes a character.) The font is dual-width. Each character is 16 pixels tall, and either 8 or 16 pixels wide. The characters are stored in a unique .hex file format invented by Roman Czyborra as a convenient way of giving each character exactly a one line specification. Conversion between this .hex format and BDF font format is trivial. HEX FILE FORMAT --------------- By convention, files containing the GNU Unifont native font format have the extension ".hex". Their format is extremely simple, consisting of two fields separated with a colon (":") and ending with a newline. The first field is the Unicode code point, in hexadecimal. For all Plane 0 code points, this is a four digit hexadecimal number. Hexadecimal digits are (in order) 0, 1, 2, 3, 4, 5, 6, 7, 8, 9, A, B, C, D, E, and F. The Unicode Standard uses a hexadecimal number to assign each character a location. These locations are called "code points" and their range is 0 through 10FFFF, inclusive. The range 0 through FFFF, inclusive, is called the Basic Multilingual Plane (BMP), or Plane 0. This plane contains most characters used by all modern scripts of the world. Because the original goal of GNU Unifont was to cover the entire Unicode Basic Multilingual Plane, a four digit hexadecimal number suffices. In the future, I plan to allow the utilities to go beyond the BMP now that coverage of the Unicode BMP is finally complete. The programs will probably handle glyphs beyond the BMP properly, but that capability is considered experimental, as the focus was to cover the BMP. The C programs allow up to an eight digit hexadecimal code point, but not all the utilities have been thoroughly tested beyond the BMP. The second field is a string of hexadecimal digits. There are 32 digits for a character that is 8 pixels wide, and 64 digits for a character that is 16 pixels wide. The good news is you don't have to worry about these long digit strings. Roman Czyborra wrote a utility, "hexdraw", to convert .hex fonts to a form that can be edited with a plain text editor, then converted back into .hex format. Paul Hardy wrote two utilities to do the same thing except with bitmapped graphics images for editing with a graphics editor: "hex2bmp" converts a block of 256 characters into a graphics file, and "bmp2hex" converts such a graphics file back into .hex format. These bitmaps display the 256 characters in a block arranged in a 16 by 16 character grid. The graphics editor must maintain the image as a monochrome (black and white) file, with one bit per pixel. After conversion from a .bmp file back to a .hex file, the next step is conversion to a BDF file and BDF can only encode a pixel being on or off (i.e., black or white only with no intermediate shades of gray). USING GRAPHICAL TOOLS --------------------- Let's use an example. Suppose you want to modify the Coptic letters in the range U+2C80..U+2CFF ("U+" is Unicode shorthand). These letters are in the upper half of the block U+2C00..U+2CFF. The Unicode utilities in this package refer to this as "page" 2C. ("Page" is not a Unicode term -- it is just a term unique to this package to refer to a block of 256 code points/characters). The steps to follow will be: 1) Convert .hex version of the page 2C range as a 16 by 16 bitmapped grid. 2) Modify the bitmap in any graphics editor, being careful to re-save it as a Windows Bitmap (.bmp) or Wireless Bitmap file when finished. 3) Convert the modified bitmap back into a .hex font file. 4) Merge the results with the original unifont.hex file. 5) Run "unidup" on the resulting file to guard against duplicate character definitions. 6) Create the new bitmapped version of the font. 7) Check the compiled font for duplicates. 8) If there are duplicates, remove them and go back to Step 5. 9) Create the new TrueType version or other versions of the font. Step 1: Convert the .hex range into a bitmap grid. Assuming our font file is named "unifont.hex", type unihex2bmp -p2C < unifont.hex > uni2C.bmp Step 2: Modify uni2C.bmp with your favorite graphics editor. Note that whatever graphics editor you use must preserve the file as a black and white bitmap (monochrome), with one bit per pixel. During editing, you can draw guidelines outside the actual 16x16 font pixel area; they will be ignored when converting back into .hex format. You can also erase the grid borders between code points on purpose or by accident, and it will have no effect on the generated .hex file. Just don't erase the code point numbers on the outer edges of the grid. The conversion from .bmp back to .hex only looks at the "U+...." and other code point numbers, and at each code point's 16x16 pixel area. Every other artifact in the final graphics file outside these areas is ignored. If a new version of Unicode adds glyphs to a page that were previously unassigned, be sure to remove the newly-assigned code point from the "unassigned.hex" file because the code point is no longer unassigned. Step 3: Convert the edited .bmp file back into .hex format: unibmp2hex < uni2C.bmp > uni2C.hex Note that the conversion from a bitmap image to a .hex file can't distinguish between a legitimate single- or double-width space character and a code point that does not have an assigned value. Therefore, space glyphs are separately contained in the spaces.hex file. Step 4: Merge the results with the original "unifont.hex" file. This requires several sub-steps: - Edit the original "unifont.hex" file and delete the lines that begin with "2C". - Insert the "uni2C.hex" file into "unifont.hex", either with a text editor such as vi or emacs, or with a Unix command such as: sort uni2C.hex unifont.hex > new-unifont.hex This second option (using "sort") is preferred, because "unidup" (in Step 5) might miss duplicate code points if your final result isn't in proper order. Step 5: Make sure there are no duplicates with "unidup": unidup < unifont.hex or unidup < new-unifont.hex depending on the name of your final font file. If there is no output, your modified font contains no duplicates. This editing is best done on an input .hex file, such as "unifont-base.hex". Step 6: Create the new bitmapped version of the font. In the font/ directory, type make hex Step 7: Check the compiled font for duplicates. Change to the font/compiled directory and run unidup < mynewfontfile.hex for whatever font file you created. Step 8: If there are duplicates, remove them in the font/ directory and go back to Step 5. Step 9: Create the new TrueType version of the font and all other bitmapped versions. From the font/ directory, type make distclean && make Then be prepared to wait a long time unless you are using a computer with plenty of RAM and CPU horsepower. Your computer should have at least 256 Megabytes of virtual memory (RAM), and at least 250 Megabytes of free disk space. To only create a BDF font, in the font/ directory just type make bdf To only create a BDF and PCF font, in the font/ directory type make pcf Creating a BDF font is the first step in creating a PCF font (not counting generating the compiled master ".hex" input file). BDF fonts can be created just with the tools in this package. PCF fonts are created by running "bdftopcf" on the BDF font. TrueType fonts require FontForge. USING HEXDRAW ------------- Roman Czyborra's original utility to edit glyphs is the "hexdraw" Perl script. Using the same script as above, Coptic, here are the steps for modifying "unifont.hex" using "hexdraw". First, realize that GNU Unifont has tens of thousands of glyphs (characters, using the term character loosely). In this example, out of the tens of thousands of glyphs, we want to modify the range U+2C80..U+2CFF (only 128 glyphs). The range U+2C80..U+2CFF could be extracted from unifont.hex by using the "egrep" utility to look for lines beginning with "2C8" through "2CF", or that range could be isolated by copying "unifont.hex" into another file, and deleting all lines except the desired range. The following steps will probably minimize typographical errors, but they aren't the only way. 1) "grep" the desired block of 256 glyphs and convert them into a text representation for editing. 2) Edit the block with a text editor, such as vi or emacs. 3) Convert the edited text file back into .hex format. 4) Delete the edited block range from the original font file. 5) Merge the two .hex files into one file. 6) Check for duplicates with "unidup". 7) Generate new fonts as described in the Using Graphical Tools section above. Step 1: Extract the desired block with grep: grep "^2C" unifont.hex | hexdraw > uni2C.txt Step 2: Edit "uni2C.txt" with a text editor. Step 3: Convert the text file back into .hex format: hexdraw < uni2C.txt > uni2C.hex Step 4: Delete the lines in the original "unifont.hex" file that begin with "2C". Step 5: Merge the two files: sort unifont.hex uni2C.hex > new-unifont.hex or use Roman's "hexmerge" utility: hexmerge unifont.hex uni2C.hex > new-unifont.hex Step 6: Check for duplicates: unidup < new-unifont.hex Of course, remove any reported duplicates. Step 7: Build the font as in the Using Graphical Tools section above. This can be as simple as typing make in the font/ directory. I (Paul Hardy) had only used hexdraw in the very beginning of my work on the GNU Unifont. Once I got my graphics programs working, I ignored it for months. Then I wanted to go through all of the Yi Syllables and Yi Radicals -- over 1000 glyphs -- to fine-tune their horizontal alignment after I drew them. hexdraw turned out to be the perfect tool for this. By printing hyphens ("-") as place holders where a pixel is off, it allowed me to verify space to the left and right of each character. I later used hexdraw for similar fine-tuning of spacing on Hangul and other glyphs. It is ideal for the task. CHECKING COVERAGE ----------------- There should never be duplicates in a .hex file. If there are, remove them before the .hex font is turned into a .bdf or other font. The notes above include making liberal use of "unidup" to avoid such a situation. The "unipagecount" program will print a hexadecimal number of code points that have coverage within each 256 code point block. The hexadecimal number will therefore range from 0 (no coverage) to 100 (= 256 decimal; full coverage). If a number is ever more than 100 hexadecimal, there's an extra character (glyph) for that page. To further look at the coverage within just one 256 code point page (using page 2C, containing Coptic, as our example) use unipagecount -p2C < unifont.hex Note that the "page number" can use upper- or lower-case letters: "-p2C" or "-p2c" will both work. That will print a 16 x 16 grid of U+2C00..U+2CFF. Of course, without placeholder glyphs for the unassigned code points from "unassigned.hex" in the U+2C00..U+2CFF range, unipagecount can give a lower number than the true coverage. Using the "-l" flag with "unipagecount" will produce an HTML table with links to corresponding graphics images. You can get an idea of how this works in the "./font/compiled" directory after running "make"; the "index.html" file in that directory will have a table with links to the 256 glyph maps in the ./font/compiled/bmp subdirectory. With unipagecount, the background color of the cells will range from red (for 0% complete in that 256 code point block) to orange (a little coverage) to yellow (more coverage) to green (complete coverage). If a cell looks light red or pink, the corresponding code page might accidentally have duplicate characters. Verify that with "sort unifont.hex | unidup" (substituting the name of your .hex file for "unifont.hex"). To see the coverage of each Unicode script, copy the file "./coverage.dat" into the same directory as the "unifont.hex" file you're examining. Then run unicoverage < unifont.hex > coverage.out This will give you all the scripts within the Unicode Basic Multilingual Plane, in order, with a percentage (0.0% through 100.0%) of each script's coverage. Note that to get the true coverage of assigned code points, you'll have to merge unassigned.hex with the rest of unifont.hex if not done by default in your setup. Using the .hex files in font/hexsrc, you can create a font with all available glyphs with sort font/hexsrc/*.hex >unifont-whole.hex and run unicoverage using the resulting "unifont-whole.hex" file. CUSTOM BUILDS ------------- The font can be built from within the "font/" directory by simply typing make Typing "make" from the top-level directory (one level above the "font/" directory) will also build the font. By default, source glyphs are read from the "font/hexsrc/" directory. Glyphs for unassigned code points are built into the font by default, but glyphs for Private Use Area code points are not built into the font. All of the .hex file names can be replaced selectively. The list of component hex file variables is: UNIFONTBASE - The bulk of Unifont scripts CJK - Most of the CJK Ideographs HANGUL - Hangul Syllables block SPACES - Space glyphs, single- and double-width UNASSIGNED - Glyphs for unassigned code points PUA - Glyphs for the Private Use Area So, for example, to build a font that includes four-digit hexadecimal code point glyphs (as white on black) for the Private Use Area, type make PUA="hexsrc/pua.hex" To build a font that includes your own special PUA glyphs, type make PUA="mycoolPUA.hex" or whatever the name of your PUA glyph .hex file is named. To create a build that includes the supplied PUA glyphs but not the Unassigned glyphs, type make PUA="hexsrc/pua.hex" UNASSIGNED="" If you create a custom font build of your own in one gigantic file, you can build with just this file by declaring all the ordinary files to be null: make UNIFONTBASE="mycustomfont.hex" CJK="" HANGUL="" UNASSIGNED="" PUA="" Note that this command did not include an override for the glyphs for spaces contained in "font/hexsrc/spaces.hex"; that is, the variable SPACES was not redefined on the command line. You could also pass the argument SPACES="", but just be aware that those spaces glyphs are in a separate file for a reason. When graphical (".bmp") glyph files are converted back into hex string (".hex") format, the "unibmp2hex" utility doesn't know if a blank glyph area is a space glyph or not, so it doesn't encode anything. The file "font/hexsrc/spaces.hex" contains glyphs that are strings of 0s, with length depending on whether the space is nominally a single- or double-width space. SEEING THE BIG PICTURE (LITERALLY!) ----------------------------------- The Unifont 6.3 release adds a new program, unifontpic. This produces a chart of all the Basic Multilingual Plane glyphs in Unifont. By default the chart is arranged as a 256-by-256 glyph table. Specifying the '-l" option produces a chart that is 16 glyphs wide by 4,096 glyphs long. See unifontpic(1) for more information. To generate a chart with all your glyphs in one giant unifont.hex file, type the command unifontpic < unifont.hex > unifont.bmp The output is a monochrome Bitmap Graphics Format (.bmp) file. If you prefer PNG files, use your favorite graphics program or conversion program to convert the BMP file to a PNG file. This utility is especially useful if you're customizing the font, for example adding your own Private Use Area glyphs. The default 256-by-256 code point chart will render satisfactorily on a sheet of paper approximately 3 feet by 3 feet at 120 dots per inch. Thus the square format is suitable for printing. The "long" version, created with "unifontpic -l", only produces 16 glyphs per row. This is more useful for scrolling through on a computer screen. GIMP can read the resulting .bmp file (at least under GNOME), but not all utilities can. The output file is over 65,536 pixel rows tall, which causes problems with some graphics programs. COMBINING CIRCLES ----------------- The earliest versions of Unifont (before the 5.1 release) used glyphs that showed dashed circles for combining characters. This is how the glyphs appear in The Unicode Standard code charts. In version 5.1, Paul Hardy was able to get combining characters to appear superimposed correctly in the TrueType version of the font (note: this won't work in the BDF or PCF versions). With combining characters working, Paul Hardy created variations of Unifont with and without combining circles, the idea being that the version without combining circles would be used to create the TrueType font. The variation with combining circles was kept for reference. Version 6.2 simplified the build to produce only one font variation, without combining circles. Version 6.3 introduces a new utility, unigencircles, to superimpose combining circles over glyphs with code points in a combining.txt file. To run unigencircles, start with the file "font/ttfsrc/combining.txt" and type a command of this form: unigencircles combining.txt < unifont.hex > unifont-circles.hex where "unifont.hex" is a single file containing all the glyphs you wish to render. Because the output is another .hex file, you can use all Unicode utilities with this file just as you would with the .hex files in "font/hexsrc". If you want to build a font from this resulting file, you could type make UNIFONTBASE="unifont-circles.hex" CJK="" HANGUL="" UNASSIGNED="" PUA="" as discussed above. In this case, if you included "font/hexsrc/spaces.hex" in the "unifont.hex" input file, you should also set SPACES="" on the command line so that you only read in your final custom "unifont-circles.hex" file. INSTALLING FONTS ON UNIX/LINUX ------------------------------ Compress PCF fonts using "gzip -9 fontname.pcf". Copy the resulting "fontname.pcf.gz" file to /usr/share/fonts/X11/misc/ or place in a local font directory if your windowing software supports that (for example, ~/.fonts/). Copy TrueType fonts to /usr/share/fonts/truetype uncompressed or place in your local font directory. Note: on some versions of Unix, such as Solaris, the name of the TrueType directory might be TrueType and might be under /usr/share/fonts/X11 -- examine the system fonts directories, then modify the font "make install" rule accordingly. On most flavors of Linux with the latest "xset" utility (including the latest Debian and Red Hat releases), the following command should allow you to start using the font immediately: xset fp rehash The safest way to make sure the system knows about the new fonts will be to restart the X Window System or even reboot. INSTALLING FONTS ON MICROSOFT WINDOWS ------------------------------------- Copy the TrueType (*.ttf) font into your C:\WINDOWS\Fonts folder. INSTALLING FONTS ON MACS ------------------------ Copy the TrueType (*.ttf) font into the Fonts folder under the Finder folder. CREATING A BRAND NEW FONT ------------------------- These tools will only produce glyphs that are 16 pixels tall, and 8 or 16 pixels wide. This current release is furthermore only fully tested over the Unicode Basic Multilingual Plane (code points from U+0000 through U+FFFF, with none above that range -- this will change in the future). The tools can be used to create and manipulate any bitmapped font within those constraints. To create a brand new font (or even to add a new script to GNU Unifont in the future), plan out the basic dimensions of the characters: - How far above the lowest pixel will the baseline appear (in other words, how many rows are necessary for descenders)? - How many pixels must be empty on top and bottom for accents (in other words, what will the height of capital letters be)? - Must glyphs be centered, left-aligned, or right-aligned? - For a Latin font, what will the "x-height" be (the height of a lower-case "x" and related letters, such as "n" and "r")? Look over the entire script and plan out a grid that is consistent for the entire script. GNU Unifont characters for the most part leave the right-most column of pixels blank if possible for left-to-right scripts. Centering is done around the fourth pixel (if a glyph is eight pixels wide) or around the eighth pixel (if a glyph is 16 pixels wide). Consistent cap heights, x-heights, descender depths, and centering will produce a better looking font. Experimenting and (above all) having fun with these utilities is the best way to learn. UPDATES TO UNICODE ------------------ If a currently unused code point is assigned to a character in the future, the font can be updated as follows: 1) Delete the code point's entry from "unassigned.hex", as that code point will no longer be unassigned. 2) Determine which existing .hex file should contain the newly defined character (examine the files to see which one contains other glyphs in the script. - "unifont-base.hex" contains most scripts - "wqy.hex" contains most CJK ideographs - "hangul-syllables.hex" contains the Hangul Syllables block If in doubt (for example, if a new script is added to Unicode and you're not sure which .hex file to augment), add the new glyphs to "unifont-base.hex". 3) Update the appropriate .hex file. 4) Consider if "./font/coverage.dat" has to be updated. Follow its existing format to insert a new script, being sure to change any previously unassigned ranges before or after the new script. 5) Make a new .hex version of the font, and verify that you didn't introduce any duplicates. 6) Run "unipagecount" and/or "unicoverage" as described above to verify that you have not mistakenly deleted any existing characters. Enjoy!