% Copyright 1990 - 1995 by AT&T Bell Laboratories. % Permission to use, copy, modify, and distribute this software % and its documentation for any purpose and without fee is hereby % granted, provided that the above copyright notice appear in all % copies and that both that the copyright notice and this % permission notice and warranty disclaimer appear in supporting % documentation, and that the names of AT&T Bell Laboratories or % any of its entities not be used in advertising or publicity % pertaining to distribution of the software without specific, % written prior permission. % AT&T disclaims all warranties with regard to this software, % including all implied warranties of merchantability and fitness. % In no event shall AT&T be liable for any special, indirect or % consequential damages or any damages whatsoever resulting from % loss of use, data or profits, whether in an action of contract, % negligence or other tortious action, arising out of or in % connection with the use or performance of this software. % Version 0 was prepared (March 1990). % Version 0.1 implemented virtual fonts. (May 1990) % Version 0.30 outputs setbounds statments, ignores rules 1sp wide (May 1991) % Version 0.60 outputs rules as penstrokes with butt ends % Version 0.62 makes the output more robust when used in a macro definition % Version 0.63 new version number only (Unix change file has // path searching) % Version 0.632 outputs a setbounds path even if no 1sp vrule appears (Jan 1997) % Version 0.64 avoids outputting wrong fonts, improves error handling (Jan 1998) % Although considerable effort has been expended to make the DVItoMP program % correct and reliable, no warranty is implied; the author disclaims any % obligation or liability for damages, including but not limited to % special, indirect, or consequential damages arising out of or in % connection with the use or performance of this software. % This program is loosely based on DVItype Version 3.0 % It converts a DVI file into a sequence of MetaPost picture expressions. % TeX is a trademark of the American Mathematical Society. % Here is TeX material that gets inserted after \input webmac \def\hang{\hangindent 3em\indent\ignorespaces} \font\ninerm=cmr9 \font\sc=cmcsc10 \let\mc=\ninerm % medium caps for names like SAIL \def\MP{MetaPost} \def\LaTeX{{\rm L\kern-.36em\raise.3ex\hbox{\sc a}\kern-.15em T\kern-.1667em\lower.7ex\hbox{E}\kern-.125emX}} \def\PASCAL{Pascal} \def\(#1){} % this is used to make section names sort themselves better \def\9#1{} % this is used for sort keys in the index \def\title{DVI$\,$\lowercase{to}MP} \def\contentspagenumber{1} \def\topofcontents{\null \def\titlepage{F} % include headline on the contents page \def\rheader{\mainfont\hfil \contentspagenumber} \vfill \centerline{\titlefont The {\ttitlefont DVItoMP} processor} \vskip 15pt \centerline{(Version 0.64, January 1998)} \vfill} \pageno=\contentspagenumber \advance\pageno by 1 @* Introduction. The \.{DVItoMP} program reads binary device-independent (``\.{DVI}'') files that are produced by document compilers such as \TeX, and converts them into a symbolic form understood by \MP. It is loosely based on the \.{DVItype} utility program that produces a more faithful symbolic form of a \.{DVI} file. The output file is a sequence of \MP\ picture expressions, one for every page in the \.{DVI} file. It makes no difference to \.{DVItoMP} where the \.{DVI} file comes from, but it is intended to process the result of running \TeX\ or \LaTeX\ on the output of \.{MPtoTEX}. Such a \.{DVI} file will contain one page for every \.{btex}$\ldots$\.{etex} block in the original input. Processing in with \.{DVItoMP} creates a corresponding sequence of \MP\ picture expressions for use as an auxiliary input file. Since \MP\ expects such files to have the extension \.{.MPX}, the output of \.{DVItoMP} is sometimes called an ``\.{MPX}'' file. The |banner| string defined here should be changed whenever \.{DVItoMP} gets modified. @d banner=='% Written by DVItoMP, Version 0.64' {the first line of the output file} @ This program is written in standard \PASCAL, except where it is necessary to use extensions; for example, \.{DVItoMP} must read files whose names are dynamically specified, and that would be impossible in pure \PASCAL. All places where nonstandard constructions are used have been listed in the index under ``system dependencies.'' @!@^system dependencies@> Many \.{DVI}-reading programs need the ability to move to a random place in a binary file. \.{DVItoMP} does not need to do this, but it does use a default |case| as in \.{TANGLE}, \.{WEAVE}, etc. @ The binary input comes from |dvi_file|, and the symbolic output goes to |mpx_file|. \PASCAL's standard |output| file is used only to print an error message if the \.{DVI} file is bad. The term |print| is used instead of |write| when this program writes on |mpx_file| just in case this helps some installations deal with system dependencies. @^system dependencies@> @d print(#)==write(mpx_file,#) @d print_ln(#)==write_ln(mpx_file,#) @d err_print(#)==write(#) @d err_print_ln(#)==write_ln(#) @p program DVI_to_MP(@!dvi_file,@!mpx_file,@!output); label @@/ const @@/ type @@/ var @@/ procedure initialize; {this procedure gets things started properly} var i:integer; {loop index for initializations} begin @@/ end; @ If the program has to stop prematurely, it goes to the `|final_end|'. Another label, |done|, is used when stopping normally. @d final_end=9999 {label for the end of it all} @d done=30 {go here when finished with a subtask} @=final_end,done; @ The following parameters can be changed at compile time to extend or reduce \.{DVItoMP}'s capacity. @= @!max_fonts=100; {maximum number of distinct fonts per \.{DVI} file} @!max_fnums=300; {maximum number of fonts plus fonts local to virtual fonts} @!max_widths=10000; {maximum number of different characters among all fonts} @!virtual_space=10000; {maximum total bytes of typesetting commands for virtual fonts} @!line_length=79; {maximum output line length (must be at least 60)} @!stack_size=100; {\.{DVI} files shouldn't |push| beyond this depth} @!name_size=1000; {total length of all font file names} @!name_length=50; {a file name shouldn't be longer than this} @ There is one more parameter that is a little harder to change because it is of type |real|. @d font_tolerance==0.00001 {font sizes should match to within this multiple of $2^{20}$ \.{DVI} units} @ Here are some macros for common programming idioms. @d incr(#) == #:=#+1 {increase a variable by unity} @d decr(#) == #:=#-1 {decrease a variable by unity} @d do_nothing == {empty statement} @ A global variable |history| keeps track of what type of errors have occurred with the hope that that \MP\ can be warned of any problems. @d spotless=0 {|history| value when no problems have been found} @d cksum_trouble=1 {|history| value there have been font checksum mismatches} @d warning_given=2 {|history| value after a recoverable error} @d fatal_error=3 {|history| value if processing had to be aborted} @= history:spotless..fatal_error; @ @= history:=spotless; @ If the \.{DVI} file is badly malformed, the whole process must be aborted; \.{DVItoMP} will give up, after issuing an error message about the symptoms that were noticed. Such errors might be discovered inside of subroutines inside of subroutines, so a procedure called |jump_out| has been introduced. This procedure, which simply transfers control to the label |final_end| at the end of the program, contains the only non-local |goto| statement in \.{DVItoMP}. @^system dependencies@> @d abort(#)==begin err_print_ln('DVItoMP abort: ',#); history:=fatal_error; jump_out; end @d bad_dvi(#)==abort('Bad DVI file: ',#,'!') @.Bad DVI file@> @d warn(#)==begin err_print_ln('DVItoMP warning: ',#); history:=warning_given; end @p procedure jump_out; begin goto final_end; end; @* The character set. Like all programs written with the \.{WEB} system, \.{DVItoMP} can be used with any character set. But it uses ASCII code internally, because the programming for portable input-output is easier when a fixed internal code is used, and because \.{DVI} files use ASCII code for file names. The next few sections of \.{DVItoMP} have therefore been copied from the analogous ones in the \.{WEB} system routines. They have been considerably simplified, since \.{DVItoMP} need not deal with the controversial ASCII codes less than @'40 or greater than @'176. If such codes appear in the font names, they will be printed as question marks. @= @!ASCII_code=" ".."~"; {a subrange of the integers} @ The original \PASCAL\ compiler was designed in the late 60s, when six-bit character sets were common, so it did not make provision for lower case letters. Nowadays, of course, we need to deal with both upper and lower case alphabets in a convenient way, especially in a program like \.{DVItoMP}. So we shall assume that the \PASCAL\ system being used for \.{DVItoMP} has a character set containing at least the standard visible characters of ASCII code (|"!"| through |"~"|). Some \PASCAL\ compilers use the original name |char| for the data type associated with the characters in text files, while other \PASCAL s consider |char| to be a 64-element subrange of a larger data type that has some other name. In order to accommodate this difference, we shall use the name |text_char| to stand for the data type of the characters in the output file. We shall also assume that |text_char| consists of the elements |chr(first_text_char)| through |chr(last_text_char)|, inclusive. The following definitions should be adjusted if necessary. @^system dependencies@> @d text_char == char {the data type of characters in text files} @d first_text_char=0 {ordinal number of the smallest element of |text_char|} @d last_text_char=127 {ordinal number of the largest element of |text_char|} @= @!text_file=packed file of text_char; @ The \.{DVItoMP} processor converts from ASCII code to the user's external character set by means of an array |xchr| that is analogous to \PASCAL's |chr| function. @= @!mpx_file:text_file; {destination for printed output} @!xchr: array [0..255] of text_char; {specifies conversion of output characters} @ To prepare the |mpx_file| for output, we |rewrite| it. @^system dependencies@> @p procedure open_mpx_file; {prepares to write text on |mpx_file|} begin rewrite(mpx_file); end; @ Under our assumption that the visible characters of standard ASCII are all present, the following assignment statements initialize the |xchr| array properly, without needing any system-dependent changes. @= for i:=0 to @'37 do xchr[i]:='?'; xchr[@'40]:=' '; xchr[@'41]:='!'; xchr[@'42]:='"'; xchr[@'43]:='#'; xchr[@'44]:='$'; xchr[@'45]:='%'; xchr[@'46]:='&'; xchr[@'47]:='''';@/ xchr[@'50]:='('; xchr[@'51]:=')'; xchr[@'52]:='*'; xchr[@'53]:='+'; xchr[@'54]:=','; xchr[@'55]:='-'; xchr[@'56]:='.'; xchr[@'57]:='/';@/ xchr[@'60]:='0'; xchr[@'61]:='1'; xchr[@'62]:='2'; xchr[@'63]:='3'; xchr[@'64]:='4'; xchr[@'65]:='5'; xchr[@'66]:='6'; xchr[@'67]:='7';@/ xchr[@'70]:='8'; xchr[@'71]:='9'; xchr[@'72]:=':'; xchr[@'73]:=';'; xchr[@'74]:='<'; xchr[@'75]:='='; xchr[@'76]:='>'; xchr[@'77]:='?';@/ xchr[@'100]:='@@'; xchr[@'101]:='A'; xchr[@'102]:='B'; xchr[@'103]:='C'; xchr[@'104]:='D'; xchr[@'105]:='E'; xchr[@'106]:='F'; xchr[@'107]:='G';@/ xchr[@'110]:='H'; xchr[@'111]:='I'; xchr[@'112]:='J'; xchr[@'113]:='K'; xchr[@'114]:='L'; xchr[@'115]:='M'; xchr[@'116]:='N'; xchr[@'117]:='O';@/ xchr[@'120]:='P'; xchr[@'121]:='Q'; xchr[@'122]:='R'; xchr[@'123]:='S'; xchr[@'124]:='T'; xchr[@'125]:='U'; xchr[@'126]:='V'; xchr[@'127]:='W';@/ xchr[@'130]:='X'; xchr[@'131]:='Y'; xchr[@'132]:='Z'; xchr[@'133]:='['; xchr[@'134]:='\'; xchr[@'135]:=']'; xchr[@'136]:='^'; xchr[@'137]:='_';@/ xchr[@'140]:='`'; xchr[@'141]:='a'; xchr[@'142]:='b'; xchr[@'143]:='c'; xchr[@'144]:='d'; xchr[@'145]:='e'; xchr[@'146]:='f'; xchr[@'147]:='g';@/ xchr[@'150]:='h'; xchr[@'151]:='i'; xchr[@'152]:='j'; xchr[@'153]:='k'; xchr[@'154]:='l'; xchr[@'155]:='m'; xchr[@'156]:='n'; xchr[@'157]:='o';@/ xchr[@'160]:='p'; xchr[@'161]:='q'; xchr[@'162]:='r'; xchr[@'163]:='s'; xchr[@'164]:='t'; xchr[@'165]:='u'; xchr[@'166]:='v'; xchr[@'167]:='w';@/ xchr[@'170]:='x'; xchr[@'171]:='y'; xchr[@'172]:='z'; xchr[@'173]:='{'; xchr[@'174]:='|'; xchr[@'175]:='}'; xchr[@'176]:='~'; for i:=@'177 to 255 do xchr[i]:='?'; @* Device-independent file format. The format of \.{DVI} files is described in many places including \.{dvitype.web} and Volume~B of D.~E. Knuth's {\sl Computers and Typesetting}. This program refers to the following command codes. @d id_byte=2 {identifies the kind of \.{DVI} files described here} @# @d set_char_0=0 {typeset character 0 and move right} @d set1=128 {typeset a character and move right} @d set_rule=132 {typeset a rule and move right} @d put1=133 {typeset a character} @d put_rule=137 {typeset a rule} @d nop=138 {no operation} @d bop=139 {beginning of page} @d eop=140 {ending of page} @d push=141 {save the current positions} @d pop=142 {restore previous positions} @d right1=143 {move right} @d w0=147 {move right by |w|} @d w1=148 {move right and set |w|} @d x0=152 {move right by |x|} @d x1=153 {move right and set |x|} @d down1=157 {move down} @d y0=161 {move down by |y|} @d y1=162 {move down and set |y|} @d z0=166 {move down by |z|} @d z1=167 {move down and set |z|} @d fnt_num_0=171 {set current font to 0} @d fnt1=235 {set current font} @d xxx1=239 {extension to \.{DVI} primitives} @d xxx4=242 {potentially long extension to \.{DVI} primitives} @d fnt_def1=243 {define the meaning of a font number} @d pre=247 {preamble} @d post=248 {postamble beginning} @d post_post=249 {postamble ending} @d undefined_commands==250,251,252,253,254,255 @* Input from binary files. We have seen that a \.{DVI} file is a sequence of 8-bit bytes. The bytes appear physically in what is called a `|packed file of 0..255|' in \PASCAL\ lingo. Packing is system dependent, and many \PASCAL\ systems fail to implement such files in a sensible way (at least, from the viewpoint of producing good production software). For example, some systems treat all byte-oriented files as text, looking for end-of-line marks and such things. Therefore some system-dependent code is often needed to deal with binary files, even though most of the program in this section of \.{DVItoMP} is written in standard \PASCAL. @^system dependencies@> One common way to solve the problem is to consider files of |integer| numbers, and to convert an integer in the range $-2^{31}\L x<2^{31}$ to a sequence of four bytes $(a,b,c,d)$ using the following code, which avoids the controversial integer division of negative numbers: $$\vbox{\halign{#\hfil\cr |if x>=0 then a:=x div @'100000000|\cr |else begin x:=(x+@'10000000000)+@'10000000000; a:=x div @'100000000+128;|\cr \quad|end|\cr |x:=x mod @'100000000;|\cr |b:=x div @'200000; x:=x mod @'200000;|\cr |c:=x div @'400; d:=x mod @'400;|\cr}}$$ The four bytes are then kept in a buffer and output one by one. (On 36-bit computers, an additional division by 16 is necessary at the beginning. Another way to separate an integer into four bytes is to use/abuse \PASCAL's variant records, storing an integer and retrieving bytes that are packed in the same place; {\sl caveat implementor!\/}) It is also desirable in some cases to read a hundred or so integers at a time, maintaining a larger buffer. We shall stick to simple \PASCAL\ in this program, for reasons of clarity, even if such simplicity is sometimes unrealistic. @= @!eight_bits=0..255; {unsigned one-byte quantity} @!byte_file=packed file of eight_bits; {files that contain binary data} @ The program deals with two binary file variables: |dvi_file| is the main input file that we are translating into symbolic form, and |tfm_file| is the current font metric file from which character-width information is being read. It is convenient to have a throw-away variable for function results when reading parts of the files that are being skipped. @= @!dvi_file:byte_file; {the input file} @!tfm_file:byte_file; {a font metric file} @!vf_file:byte_file; {a virtual font file} @!down_the_drain:integer; {a ``write-only'' variable} @ To prepare these files for input, we |reset| them. An extension of \PASCAL\ is needed in the case of |tfm_file|, since we want to associate it with external files whose names are specified dynamically (i.e., not known at compile time). The following code assumes that `|reset(f,s)|' does this, when |f| is a file variable and |s| is a string variable that specifies the file name. If |eof(f)| is true immediately after |reset(f,s)| has acted, these routines assume that no file named |s| is accessible. @^system dependencies@> @p procedure open_dvi_file; {prepares to read packed bytes in |dvi_file|} begin reset(dvi_file); if eof(dvi_file) then abort('DVI file not found'); end; @# function open_tfm_file:boolean; {prepares to read packed bytes in |tfm_file|} begin reset(tfm_file,cur_name); open_tfm_file:=(not eof(tfm_file)); end; @# function open_vf_file:boolean; {prepares to read packed bytes in |vf_file|} begin reset(vf_file,cur_name); open_vf_file:=(not eof(vf_file)); end; @ If you looked carefully at the preceding code, you probably asked, ``What is |cur_name|?'' Good question. It's a global variable: |cur_name| is a string variable that will be set to the current font metric file name before |open_tfm_file| is called. @= @!cur_name:packed array[1..name_length] of char; {external name, with no lower case letters} @ It turns out to be convenient to read four bytes at a time, when we are inputting from \.{TFM} files. The input goes into global variables |b0|, |b1|, |b2|, and |b3|, with |b0| getting the first byte and |b3| the fourth. @= @!b0,@!b1,@!b2,@!b3: eight_bits; {four bytes input at once} @ The |read_tfm_word| procedure sets |b0| through |b3| to the next four bytes in the current \.{TFM} file. @^system dependencies@> @p procedure read_tfm_word; begin read(tfm_file,b0); read(tfm_file,b1); read(tfm_file,b2); read(tfm_file,b3); end; @ Input can come from from three different sources depending on the settings of global variables. When |vf_reading| is true, we read from the \.{VF} file. Otherwise, input can either come directly from |dvi_file| or from a buffer |cmd_buf|. The latter case applies whenever |buf_ptr= @!vf_reading:boolean; {should input come from |vf_file|?} @!cmd_buf:packed array [0..virtual_space] of quarter_word; {commands for virtual characters} @!buf_ptr:0..virtual_space; {|cmd_buf| index for the next byte} @ @= vf_reading:=false; buf_ptr:=virtual_space; @ It is probably not critical that |cmd_buf| be packed as efficiently as possible, but we define a new type just in case it is necessary to for |cmd_buf| entries to be in the range |-128..127|. @^system dependencies@> @d qi(#)==# {convert from |eight_bits| to |quarter_word|} @d qo(#)==# {convert from |quarter_word| to |eight_bits|} @= quarter_word=0..255; {a one byte quantity as stored in |cmd_buf|} @ We shall use a set of simple functions to read the next byte or bytes from the current input source. There are seven possibilities, each of which is treated as a separate function in order to minimize the overhead for subroutine calls. @p function get_byte:integer; {returns the next byte, unsigned} var b:eight_bits; begin @; get_byte:=b; end; @# function signed_byte:integer; {returns the next byte, signed} var b:eight_bits; begin @; if b<128 then signed_byte:=b @+ else signed_byte:=b-256; end; @# function get_two_bytes:integer; {returns the next two bytes, unsigned} var a,@!b:eight_bits; begin @; get_two_bytes:=a*256+b; end; @# function signed_pair:integer; {returns the next two bytes, signed} var a,@!b:eight_bits; begin @; if a<128 then signed_pair:=a*256+b else signed_pair:=(a-256)*256+b; end; @# function get_three_bytes:integer; {returns the next three bytes, unsigned} var a,@!b,@!c:eight_bits; begin @; get_three_bytes:=(a*256+b)*256+c; end; @# function signed_trio:integer; {returns the next three bytes, signed} var a,@!b,@!c:eight_bits; begin @; if a<128 then signed_trio:=(a*256+b)*256+c else signed_trio:=((a-256)*256+b)*256+c; end; @# function signed_quad:integer; {returns the next four bytes, signed} var a,@!b,@!c,@!d:eight_bits; begin @; if a<128 then signed_quad:=((a*256+b)*256+c)*256+d else signed_quad:=(((a-256)*256+b)*256+c)*256+d; end; @ @= if vf_reading then read(vf_file,b) else if buf_ptr=virtual_space then read(dvi_file,b) else begin b:=qo(cmd_buf[buf_ptr]); incr(buf_ptr); end @ @= if vf_reading then begin read(vf_file,a); read(vf_file,b); end else if buf_ptr=virtual_space then begin read(dvi_file,a); read(dvi_file,b); end else if buf_ptr+2>n_cmds then abort('Error detected while interpreting a virtual font') @.Error detected while...@> else begin a:=qo(cmd_buf[buf_ptr]); b:=qo(cmd_buf[buf_ptr+1]); buf_ptr:=buf_ptr+2; end @ @= if vf_reading then begin read(vf_file,a); read(vf_file,b); read(vf_file,c); end else if buf_ptr=virtual_space then begin read(dvi_file,a); read(dvi_file,b); read(dvi_file,c); end else if buf_ptr+3>n_cmds then abort('Error detected while interpreting a virtual font') @.Error detected while...@> else begin a:=qo(cmd_buf[buf_ptr]); b:=qo(cmd_buf[buf_ptr+1]); c:=qo(cmd_buf[buf_ptr+2]); buf_ptr:=buf_ptr+3; end @ @= if vf_reading then begin read(vf_file,a); read(vf_file,b); read(vf_file,c); read(vf_file,d); end else if buf_ptr=virtual_space then begin read(dvi_file,a); read(dvi_file,b); read(dvi_file,c); read(dvi_file,d); end else if buf_ptr+4>n_cmds then abort('Error detected while interpreting a virtual font') @.Error detected while...@> else begin a:=qo(cmd_buf[buf_ptr]); b:=qo(cmd_buf[buf_ptr+1]); c:=qo(cmd_buf[buf_ptr+2]); d:=qo(cmd_buf[buf_ptr+3]); buf_ptr:=buf_ptr+4; end @* Data structures for fonts. \.{DVI} file format does not include information about character widths, since that would tend to make the files a lot longer. But a program that reads a \.{DVI} file is supposed to know the widths of the characters that appear in \\{set\_char} commands. Therefore \.{DVItoMP} looks at the font metric (\.{TFM}) files for the fonts that are involved. @.TFM {\rm files}@> @ For purposes of this program, the only thing we need to know about a given character |c| in a non-virtual font |f| is the width. For the font as a whole, all we need is the symbolic name to use in the \.{MPX} file. This information appears implicitly in the following data structures. The current number of fonts defined is |nf|. Each such font has an internal number |f|, where |0<=f= @!font_num:array [0..max_fnums] of integer; {external font numbers} @!internal_num:array [0..max_fnums] of integer; {internal font numbers} @!local_only:array [0..max_fonts] of boolean; {|font_num| meaningless?} @!font_name:array [0..max_fonts] of 0..name_size; {starting positions of external font names} @!names:array [0..name_size] of ASCII_code; {characters of names} @!area_length:array [0..max_fonts] of integer; {length of area part of font name} @!font_scaled_size:array [0..max_fonts] of real; {scale factors over $2^{20}$} @!font_design_size:array [0..max_fonts] of real; {design sizes over $2^{20}$} @!font_check_sum:array [0..max_fonts] of integer; {check sum from the |font_def|} @!font_bc:array [0..max_fonts] of integer; {beginning characters in fonts} @!font_ec:array [0..max_fonts] of integer; {ending characters in fonts} @!info_base:array [0..max_fonts] of integer; {index into |width| and |cmd_ptr| tables} @!width:array [0..max_widths] of integer; {character widths, in units $2^{-20}$ of design size} @!fbase:array [0..max_fonts] of integer; {index into |font_num| for local fonts} @!ftop:array [0..max_fonts] of integer; {|font_num| index where local fonts stop} @!cmd_ptr:array [0..max_widths] of integer; {starting positions in |cmd_buf|} @!nf:0..max_fonts; {the number of known fonts} @!vf_ptr:max_fonts..max_fnums; {next |font_num| entry for virtual font font tables} @!info_ptr:0..max_widths; {allocation pointer for |width| and |cmd_ptr| tables} @!n_cmds:0..virtual_space; {number of occupied cells in |cmd_buf|} @!cur_fbase,@!cur_ftop:0..max_fnums; {currently applicable part of the |font_num| table} @ @= nf:=0; info_ptr:=0; font_name[0]:=0; vf_ptr:=max_fnums; cur_fbase:=0; cur_ftop:=0; @ Printing the name of a given font is easy except that a procedure |print_char| is needed to actually send an |ASCII_code| to the \.{MPX} file. @p @@; procedure print_font(@!f:integer); {|f| is an internal font number} var k:0..name_size; {index into |names|} begin if (f<0)or(f>=nf) then bad_dvi('Undefined font') else begin for k:=font_name[f] to font_name[f+1]-1 do print_char(names[k]); end; end; @ Sometimes a font name is needed as part of an error message. @d font_warn(#)==begin err_print('DVItoMP warning: ',#); font_warn_end @d font_warn_end(#)==err_print_font(#); history:=warning_given; end @d font_abort(#)==begin err_print('DVItoMP abort: ',#); font_abort_end @d font_abort_end(#)==err_print_font(#); history:=fatal_error; jump_out; end @p procedure err_print_font(@!f:integer); {|f| is an internal font number} var k:0..name_size; {index into |names|} begin for k:=font_name[f] to font_name[f+1]-1 do err_print(xchr[names[k]]); err_print_ln(' '); end; @ When we encounter a font definition, we save the name, checksum, and size information, but we don't actaully read the \.{TFM} or \.{VF} file until we are about to use the font. If a matching font is not already defined, we then allocate a new internal font number. The following subroutine does the necessary things when a \\{fnt\_def} command is encountered in the \.{DVI} file or in a \.{VF} file. It assumes that the first argument has already been parsed and is given by the parameter~|e|. @p @@; procedure define_font(@!e:integer); {|e| is an external font number} var @!i:integer; {index into |font_num| and |internal_num|} @!n:integer; {length of the font name and area} @!k:integer; {general purpose loop counter} @!x:integer; {a temporary value for scaled size computation} begin if nf=max_fonts then abort('DVItoMP capacity exceeded (max fonts=', max_fonts:1,')!'); @.DVItoMP capacity exceeded...@> @; @; internal_num[i]:=match_font(nf,true); if internal_num[i]=nf then begin info_base[nf]:=max_widths; {indicate that the info isn't loaded yet} local_only[nf]:=vf_reading; incr(nf); end; end; @ @= if vf_ptr=nf then abort('DVItoMP capacity exceeded (max font numbers=', max_fnums:1,')'); @.DVItoMP capacity exceeded...@> if vf_reading then begin font_num[nf]:=0; i:=vf_ptr; decr(vf_ptr); end else i:=nf; font_num[i]:=e @ @= font_check_sum[nf]:=signed_quad; @; n:=get_byte; area_length[nf]:=n; n:=n+get_byte; if font_name[nf]+n>name_size then abort('DVItoMP capacity exceeded (name size=',name_size:1,')!'); @.DVItoMP capacity exceeded...@> font_name[nf+1]:=font_name[nf]+n; for k:=font_name[nf] to font_name[nf+1]-1 do names[k]:=get_byte @ The scaled size and design size are stored in \.{DVI} units divided by $2^20$. The units for scaled size are a little different if we are reading a virtual font, but this will be corrected when the scaled size is used. The scaled size also needs to be truncated to at most 23 significant bits in order to make the character width calculation match what \TeX\ does. @= x:=signed_quad; k:=1; while x>@'40000000 do begin x:=x div 2; k:=k+k; end; font_scaled_size[nf]:=x*k/1048576.0; if vf_reading then font_design_size[nf]:=signed_quad*dvi_per_fix/1048576.0 else font_design_size[nf]:=signed_quad/1048576.0; @ @= @!dvi_per_fix:real; {converts points scaled $2^{20}$ to \.{DVI} units} @ The |match_font| function tries to find a match for the font with internal number~|ff|, returning |nf| or the number of the matching font. If |exact=true|, the name and scaled size should match. Otherwise the scaled size need not match but the font found must be already loaded, not just defined. @= function match_font(ff:integer; exact:boolean):integer; label done, 99; var @!f:0..max_fonts; {font number being tested} @!ss,@!ll:0..name_size; {starting point and length of name of font |ff|} @!k,@!s:0..name_size; {registers for comparing font names} begin ss:=font_name[ff]; ll:=font_name[ff+1]-ss; f:=0; while fff then begin @; if exact then begin if abs(font_scaled_size[f]-font_scaled_size[ff]) <= font_tolerance then begin if not vf_reading then if local_only[f] then begin font_num[f]:=font_num[ff]; local_only[f]:=false; end else if font_num[f]<>font_num[ff] then goto 99; goto done; end; end else if info_base[f]<>max_widths then goto done; end; 99:incr(f); end; done:if f; match_font:=f; end; @ @= if (area_length[f]font_name[f+1]-font_name[f]) then goto 99; s:=font_name[f]; k:=ll; while k>0 do begin decr(k); if names[s+k]<>names[ss+k] then goto 99; end @ @= if abs(font_design_size[f]-font_design_size[ff]) > font_tolerance then font_warn('Inconsistent design sizes given for ')(ff) @.Inconsistent design sizes@> else if font_check_sum[f]<>font_check_sum[ff] then font_warn('Checksum mismatch for ')(ff) @.Checksum mismatch@> @* Reading ordinary fonts. An auxiliary array |in_width| is used to hold the widths as they are input. The global variable |tfm_check_sum| is set to the check sum that appears in the current \.{TFM} file. @= @!in_width:array[0..255] of integer; {\.{TFM} width data in \.{DVI} units} @!tfm_check_sum:integer; {check sum found in |tfm_file|} @ Here is a procedure that absorbs the necessary information from a \.{TFM} file, assuming that the file has just been successfully reset so that we are ready to read its first byte. (A complete description of \.{TFM} file format appears in the documentation of \.{TFtoPL} and will not be repeated here.) The procedure does not check the \.{TFM} file for validity, nor does it give explicit information about what is wrong with a \.{TFM} file that proves to be invalid. The procedure simply aborts the program if it detects anything amiss in the \.{TFM} data. @p procedure in_TFM(@!f:integer); {input \.{TFM} data for font |f| or abort} label 9997, {go here when the format is bad} 9999; {go here to exit} var k:integer; {index for loops} @!lh:integer; {length of the header data, in four-byte words} @!nw:integer; {number of words in the width table} @!wp:0..max_widths; {new value of |info_ptr| after successful input} begin @; @; @; @; fbase[f]:=0; ftop[f]:=0; info_ptr:=wp; goto 9999; 9997: font_abort('Bad TFM file for ')(f); @.Bad TFM file@> 9999: end; @ @= read_tfm_word; lh:=b2*256+b3; read_tfm_word; font_bc[f]:=b0*256+b1; font_ec[f]:=b2*256+b3; if font_ec[f]max_widths then abort('DVItoMP capacity exceeded (width table size=',max_widths:1,')!'); @.DVItoMP capacity exceeded...@> wp:=info_ptr+font_ec[f]-font_bc[f]+1; read_tfm_word; nw:=b0*256+b1; if (nw=0)or(nw>256) then goto 9997; for k:=1 to 3+lh do begin if eof(tfm_file) then goto 9997; read_tfm_word; if k=4 then if b0<128 then tfm_check_sum:=((b0*256+b1)*256+b2)*256+b3 else tfm_check_sum:=(((b0-256)*256+b1)*256+b2)*256+b3; end; @ @= if wp>0 then for k:=info_ptr to wp-1 do begin read_tfm_word; if b0>nw then goto 9997; width[k]:=b0; end; @ No fancy width calculation is needed here because \.{DVItoMP} stores widths in their raw form as multiples of the design size scaled by $2^{20}$. The |font_scaled_size| entries have been computed so that the final width compution can be done in floating point if enough precision is available. @= for k:=0 to nw-1 do begin read_tfm_word; if b0>127 then b0:=b0-256; in_width[k]:=((b0*@'400+b1)*@'400+b2)*@'400+b3; end @ The width compution uses a scale factor |dvi_scale| that will be introduced later. It is equal to one when not typesetting a character from a virtual font. In that case, the following expressions do the width computation that is so important in \.{DVItype}. It is less important here because it is impractical to guarantee precise character positioning in \MP\ output. Nevertheless, the width compution will be precise if reals have at least 46-bit mantissas and |round(x-.5)| is equivalent to $\lfloor x\rfloor$. It may be a good idea to modify this computation if these conditions are not met. @^system dependencies@> @= round(dvi_scale*font_scaled_size[f]*char_width(f)(c)-0.5) @ @= round(dvi_scale*font_scaled_size[cur_font]*char_width(cur_font)(p)-0.5) @ @= if in_width[0]<>0 then goto 9997; {the first width should be zero} info_base[f]:=info_ptr-font_bc[f]; if wp>0 then for k:=info_ptr to wp-1 do width[k]:=in_width[width[k]] @* Reading virtual fonts. The |in_VF| procedure absorbs the necessary information from a \.{VF} file that has just been reset so that we are ready to read the first byte. (A complete description of \.{VF} file format appears in the documention of \.{VFtoVP}). Like |in_TFM|, this procedure simply aborts the program if it detects anything wrong with the \.{VF} file. @p @@; procedure in_VF(f:integer); {read \.{VF} data for font |f| or abort} label 9997, {go here to abort} 9999; {go here to exit} var @!p:integer; {a byte from the \.{VF} file} @!was_vf_reading:boolean; {old value of |vf_reading|} @!c:integer; {the current character code} @!limit:integer; {space limitations force character codes to be less than this} @!w:integer; {a \.{TFM} width being read} begin was_vf_reading:=vf_reading; vf_reading:=true; @;@/ @;@/ p:=get_byte; while p>=fnt_def1 do begin if p>fnt_def1+3 then goto 9997; define_font(first_par(p)); p:=get_byte; end; while p<=242 do begin if eof(vf_file) then goto 9997; @; @; p:=get_byte; end; if p=post then begin @; goto 9999; end; 9997:font_abort('Bad VF file for ')(f); 9999: vf_reading:=was_vf_reading; end; @ @= p:=get_byte; if p<>pre then goto 9997; p:=get_byte; {fetch the identification byte} if p<>202 then goto 9997; p:=get_byte; {fetch the length of the introductory comment} while p>0 do begin decr(p); down_the_drain:=get_byte; end; tfm_check_sum:=signed_quad; down_the_drain:=signed_quad; {skip over the design size} @ @= ftop[f]:=vf_ptr; if vf_ptr=nf then abort('DVItoMP capacity exceeded (max font numbers=', max_fnums:1,')'); @.DVItoMP capacity exceeded...@> decr(vf_ptr); info_base[f]:=info_ptr; limit:=max_widths-info_base[f];@/ font_bc[f]:=limit; font_ec[f]:=0 @ @= if p=242 then begin p:=signed_quad; c:=signed_quad; w:=signed_quad; if c<0 then goto 9997; end else begin c:=get_byte; w:=get_three_bytes; end; if c>=limit then abort('DVItoMP capacity exceeded (max widths=', max_widths:1,')!'); @.DVItoMP capacity exceeded...@> if cfont_ec[f] then font_ec[f]:=c; char_width(f)(c):=w @ @= if n_cmds+p>=virtual_space then abort('DVItoMP capacity exceeded (virtual font space=',virtual_space:1,')!'); @.DVItoMP capacity exceeded...@> start_cmd(f)(c):=n_cmds; while p>0 do begin cmd_buf[n_cmds]:=qi(get_byte); incr(n_cmds); decr(p); end; cmd_buf[n_cmds]:=qi(eop); {add the end-of-packet marker} incr(n_cmds) @ There are unused |width| and |cmd_ptr| entries if |font_bc[f]>0| but it isn't worthwhile to slide everything down just to save a little space. @= fbase[f]:=vf_ptr+1; info_ptr:=info_base[f]+font_ec[f] @* Loading fonts. The character width information for a font is loaded when the font is selected for the first time. This information might already be loaded if the font has already been used at a different scale factor. Otherwise, we look for a \.{VF} file, or failing that, a \.{TFM} file. All this is done by the |select_font| function that takes an external font number~|e| and returns the corresponding internal font number with the width information loaded. @p function select_font(@!e:integer):integer; var @!f:0..max_fonts; {the internal font number} @!ff:0..max_fonts; {internal font number for an existing version} @!k,@!l:integer; {general purpose loop counters} begin @; if info_base[f]=max_widths then begin ff:=match_font(f,false); if ff else begin @; if open_vf_file then in_VF(f) else begin @; if not open_tfm_file then font_abort('No TFM file found for ')(f); @.no TFM file found@> in_TFM(f); end; @; end; @; end; select_font:=f; end; @ @= if cur_ftop<=nf then cur_ftop:=nf; font_num[cur_ftop]:=e; k:=cur_fbase; while (font_num[k]<>e)or local_only[k] do incr(k); if k=cur_ftop then abort('Undefined font selected'); f:=internal_num[k] @ @= begin font_bc[f]:=font_bc[ff]; font_ec[f]:=font_ec[ff]; info_base[f]:=info_base[ff]; fbase[f]:=fbase[ff]; ftop[f]:=ftop[ff]; end @ If |area_length[f]=0|, i.e., if no font directory has been specified, \.{DVItoMP} is supposed to use the default font directory, which is a system-dependent place where the standard fonts are kept. The string variable |default_directory| contains the name of this area. @^system dependencies@> @d default_directory_name=='TeXfonts:' {change this to the correct name} @d default_directory_name_length=9 {change this to the correct length} @= @!default_directory:packed array[1..default_directory_name_length] of char; @ @= default_directory:=default_directory_name; @ The string |cur_name| is supposed to be set to the external name of the \.{VF} file for the current font. This usually means that we need to prepend the name of the default directory, and to append the suffix `\.{.VF}'. Furthermore, we change lower case letters to upper case, since |cur_name| is a \PASCAL\ string. @^system dependencies@> @= for k:=1 to name_length do cur_name[k]:=' '; if area_length[f]=0 then begin for k:=1 to default_directory_name_length do cur_name[k]:=default_directory[k]; l:=default_directory_name_length; end else l:=0; for k:=font_name[f] to font_name[f+1]-1 do begin incr(l); if l+3>name_length then abort('DVItoMP capacity exceeded (max font name length=', name_length:1,')!'); @.DVItoMP capacity exceeded...@> if (names[k]>="a")and(names[k]<="z") then cur_name[l]:=xchr[names[k]-@'40] else cur_name[l]:=xchr[names[k]]; end; cur_name[l+1]:='.'; cur_name[l+2]:='V'; cur_name[l+3]:='F' @ It is fairly simple to change a \.{VF} file name to a \.{TFM} file name. @^system dependencies@> @= l:=area_length[f]; if l=0 then l:=default_directory_name_length; l:=l+font_name[f+1]-font_name[f]; if l+4>name_length then abort('DVItoMP capacity exceeded (max font name length=', name_length:1,')!'); @.DVItoMP capacity exceeded...@> cur_name[l+2]:='T'; cur_name[l+3]:='F'; cur_name[l+4]:='M' @ @= begin if (font_check_sum[f]<>0)and(tfm_check_sum<>0)and@| (font_check_sum[f]<>tfm_check_sum) then begin err_print('DVItoMP warning: Checksum mismatch for '); @.Checksum mismatch@> err_print_font(f); if history=spotless then history:=cksum_trouble; end; end @* Low level output routines. One of the basic output operations is to write a \MP\ string expression for a sequence of characters to be typeset. The main difficulties are that such strings can contain arbitrary eight-bit bytes and there is no fixed limit on the length of the string that needs to be produced. In extreme cases this can lead to expressions such as $$\vcenter{ \hbox{\.{char7\&char15\&char31\&"?FWayzz"}} \hbox{\.{\&"zzaF"\&char15\&char3\&char31}} \hbox{\.{\&"Nxzzzzzzzwvtsqo"}}} $$ @ A global variable |state| keeps track of the output process. When |state=normal| we have begun a quoted string and the next character should be a printable character or a closing quote. When |state=special| the last thing printed was a ``\.{char}'' construction or a closing quote and an ampersand should come next. The starting condition |state=initial| is a lot like |state=special|, except no ampersand is required. @d special=0 {the |state| after printing a ``\.{char}'' expression} @d normal=1 {the |state| value in a quoted string} @d initial=2 {initial |state|} @= state:special..initial; {controls the process of printing a string} print_col:0..line_length; {there are at most this many characters on the current line} @ To print a string on the \.{MPX} file, initialize |print_col|, ensure that |state=initial|, and pass the characters one-at-a-time to |print_char|. @= procedure print_char(@!c:eight_bits); var @!printable:boolean; {is it safe to print |xchr[c]|?} @!l:integer; {number of characters to print |c| or the \.{char} expression} begin printable:=(c>=" ")and(c<="~")and(c<>""""); if printable then l:=1 else if c<10 then l:=5 else if c<100 then l:=6 else l:=7; if print_col+l>line_length-2 then begin if state=normal then begin print('"'); state:=special; end; print_ln(' '); print_col:=0; end; @; end; @ @= if state=normal then if printable then print(xchr[c]) else begin print('"&char',c:1); print_col:=print_col+2; end else begin if state=special then begin print('&'); incr(print_col); end; if printable then begin print('"',xchr[c]); incr(print_col); end else print('char',c:1); end; print_col:=print_col+l; if printable then state:=normal @+else state:=special @ The |end_char_string| procedure gets the string ended properly and ensures that there is room for |l| more characters on the output line. @= procedure end_char_string(@!l:integer); begin while state>special do begin print('"'); incr(print_col); decr(state); end; if print_col+l>line_length then begin print_ln(' '); print_col:=0; end; state:=initial; {get ready to print the next string} end; @ Since |end_char_string| resets |state:=initial|, all we have to do is set |state:=initial| once at the beginning. @= state:=initial; @ Characters and rules are positioned according to global variables |h| and~|v| as will be explained later. We also need scale factors that convert quantities to the right units when they are printed in the \.{MPX} file. Even though all variable names in the \MP\ output are made local via \.{save} commands, it is still desirable to preceed them with underscores. This makes the output more likely to work when used in a macro definition, since the generated variables names must not collide with formal parameters in such cases. @= @!h,@!v:integer; {the current position in \.{DVI} units} @!conv:real; {converts \.{DVI} units to \MP\ points} @!mag:real; {magnification factor times 1000} @ @p @@; procedure do_set_char(@!f,@!c:integer); begin if (cfont_ec[f]) then abort('attempt to typeset invalid character ',c:1); @.attempt to typeset...@> if (h<>str_h2)or(v<>str_v)or(f<>str_f)or(dvi_scale<>str_scale) then begin if str_f>=0 then finish_last_char else if not fonts_used then @; if not font_used[f] then @; print('_s('); print_col:=3;@/ str_scale:=dvi_scale; str_f:=f; str_v:=v; str_h1:=h; end; print_char(c); str_h2:=h+@; end; @ @= @!font_used:array[0..max_fonts] of boolean; {has this font been used on this page?} @!fonts_used:boolean; {has any font been used on this page?} @!rules_used:boolean; {has any rules been set on this page?} @!str_h1,str_v:integer; {starting position for current output string} @!str_h2:integer; {where the current output string ends} @!str_f:integer; {internal font number for the current output string} @!str_scale:real; {value of |dvi_scale| for the current output string} @ The |font_used| array is not initialized until it is actually time to output a character. @= begin k:=0; while (k= font_used[f]:=false; @ @= begin font_used[f]:=true; print('_n',f:1,'='); print_col:=6; print_font(f); end_char_string(1); print_ln(';'); end @ We maintain the invariant that |str_f=-1| when there is no output string under construction. @= procedure finish_last_char; var @!m,@!x,@!y:real; {font scale factor and \MP\ coordinates of reference point} begin if str_f>=0 then begin m:=str_scale*font_scaled_size[str_f]*mag/font_design_size[str_f];@/ x:=conv*str_h1; y:=conv*(-str_v); if (abs(x)>=4096.0)or(abs(y)>=4096.0)or(m>=4096.0)or(m<0) then begin warn('text scaled ',m:1:1,@| ' at (',x:1:1,',',y:1:1,') is out of range'); end_char_string(60); end else end_char_string(40); print_ln(',_n',str_f:1,',',m:1:5,',',x:1:4,',',y:1:4,');'); str_f:=-1; end; end; @ Setting rules is fairly simple. @p procedure do_set_rule(@!ht,@!wd:integer); var @!xx1,@!yy1,@!xx2,@!yy2,@!ww:real; {\MP\ coordinates of lower-left and upper-right corners} begin if wd=1 then @ else if (ht>0)or(wd>0) then begin if str_f>=0 then finish_last_char; if not rules_used then begin rules_used:=true;@/ print_ln('interim linecap:=0;');@/ print_ln('vardef _r(expr _a,_w) ='); print_ln(' addto _p doublepath _a withpen pencircle scaled _w enddef;'); end; @; if (abs(xx1)>=4096.0)or(abs(yy1)>=4096.0)or@| (abs(xx2)>=4096.0)or(abs(yy2)>=4096.0)or(ww>=4096.0) then warn('hrule or vrule near (',xx1:1:1,',',yy1:1:1,') is out of range'); print_ln('_r((',xx1:1:4,',',yy1:1:4,')..(',xx2:1:4,',',yy2:1:4, '), ',ww:1:4,');'); end; end; @ @= xx1:=conv*h; yy1:=conv*(-v); if wd>ht then begin xx2:=xx1+conv*wd; ww:=conv*ht;@/ yy1:=yy1+0.5*ww; yy2:=yy1; end else begin yy2:=yy1+conv*ht; ww:=conv*wd;@/ xx1:=xx1+0.5*ww; xx2:=xx1; end @ Rules of width one dvi unit are not typeset since \.{MPtoTeX} adds an extraneous rule of this width in order to allow \.{DVItoMP} to deduce the dimensions of the boxes it ships out. The box width is the left edge of the last such rule; the height and depth are at the top and bottom of the rule. There should be only one special rule per picture but there could be more if the user tries to typeset his own one-dvi-unit rules. In this case the dimension-determining rule is the last one in the picture. @= begin pic_wd:=h; pic_dp:=v; pic_ht:=ht-v; end @ @= pic_dp, pic_ht, pic_wd: integer; {picture dimensions from special rule} @ The following initialization and clean-up is required. We do a little more initialization than is absolutely necessary since some compilers might complain if the variables are uninitialized when |do_set_char| tests them. @p procedure start_picture; begin fonts_used:=false; rules_used:=false; str_f:=-1;@/ str_v:=0; str_h2:=0; str_scale:=1.0; {values don't matter} print_ln('begingroup save _p,_r,_s,_n; picture _p; _p=nullpicture;'); end; @# procedure stop_picture; var @!w,@!h,@!dd:real; {width, height, negative depth in PostScript points} begin if str_f>=0 then finish_last_char; @; print_ln('_p endgroup'); end; @ @= dd:=-pic_dp*conv; w:=conv*pic_wd; h:=conv*pic_ht;@/ print_ln('setbounds _p to (0,',dd:1:4,')--(',w:1:4,',',dd:1:4,')--'); print_ln(' (',w:1:4,',',h:1:4,')--(0,',h:1:4,')--cycle;') @* Translation to symbolic form. The main work of \.{DVItoMP} is accomplished by the |do_dvi_commands| procedure, which produces the output for an entire page, assuming that the |bop| command for that page has already been processed. This procedure is essentially an interpretive routine that reads and acts on the \.{DVI} commands. It is also capable of executing the typesetting commands for a character in a virtual font. @ The definition of \.{DVI} files refers to six registers, $(h,v,w,x,y,z)$, which hold integer values in \.{DVI} units. These units come directly from the input file except they need to be rescaled when typesetting characters from a virtual font. The stack of $(h,v,w,x,y,z)$ values is represented by six arrays called |hstack|, \dots, |zstack|. @= @!w,@!x,@!y,@!z:integer; {current state values (|h| and |v| have already been declared)} @!hstack,@!vstack,@!wstack,@!xstack,@!ystack,@!zstack: array [0..stack_size] of integer; {pushed down values in \.{DVI} units} @!stk_siz:integer; {the current stack size} @!dvi_scale:real; {converts units of current input source to \.{DVI} units} @ @= dvi_scale:=1.0; stk_siz:=0; h:=0; v:=0 @ Next, we need procedures to handle |push| and |pop| commands. @p procedure do_push; begin if stk_siz=stack_size then abort('DVItoMP capacity exceeded (stack size=',stack_size:1,')'); @.DVItoMP capacity exceeded...@> hstack[stk_siz]:=h; vstack[stk_siz]:=v; wstack[stk_siz]:=w; xstack[stk_siz]:=x; ystack[stk_siz]:=y; zstack[stk_siz]:=z; incr(stk_siz); end; @# procedure do_pop; begin if stk_siz=0 then bad_dvi('attempt to pop empty stack') else begin decr(stk_siz); h:=hstack[stk_siz]; v:=vstack[stk_siz]; w:=wstack[stk_siz]; x:=xstack[stk_siz]; y:=ystack[stk_siz]; z:=zstack[stk_siz]; end; end; @ We need to define the |set_virtual_char| procedure now because it is mutually recursive with |do_dvi_commands|. This is really a supervisory @^recursion@> procedure that calls |do_set_char| or adjusts the input source to read typesetting commands for a character in a virtual font. @p procedure do_dvi_commands;forward;@t\2@> procedure set_virtual_char(@!f,@!c:integer); var @!old_scale:real; {original value of |dvi_scale|} @!old_buf_ptr:0..virtual_space; {original value of the input pointer |buf_ptr|} @!old_fbase,@!old_ftop:0..max_fnums; {originally applicable part of the |font_num| table} begin if fbase[f]=0 then do_set_char(f,c) else begin old_fbase:=cur_fbase; old_ftop:=cur_ftop; cur_fbase:=fbase[f]; cur_ftop:=ftop[f];@/ old_scale:=dvi_scale; dvi_scale:=dvi_scale*font_scaled_size[f]; old_buf_ptr:=buf_ptr; buf_ptr:=start_cmd(f)(c);@/ do_push; do_dvi_commands; do_pop;@/ buf_ptr:=old_buf_ptr; dvi_scale:=old_scale; cur_fbase:=old_fbase; cur_ftop:=old_ftop; end; end; @ Before we get into the details of |do_dvi_commands|, it is convenient to consider a simpler routine that computes the first parameter of each opcode. @d four_cases(#)==#,#+1,#+2,#+3 @d eight_cases(#)==four_cases(#),four_cases(#+4) @d sixteen_cases(#)==eight_cases(#),eight_cases(#+8) @d thirty_two_cases(#)==sixteen_cases(#),sixteen_cases(#+16) @d sixty_four_cases(#)==thirty_two_cases(#),thirty_two_cases(#+32) @= function first_par(o:eight_bits):integer; begin case o of sixty_four_cases(set_char_0),sixty_four_cases(set_char_0+64): first_par:=o-set_char_0; set1,put1,fnt1,xxx1,fnt_def1: first_par:=get_byte; set1+1,put1+1,fnt1+1,xxx1+1,fnt_def1+1: first_par:=get_two_bytes; set1+2,put1+2,fnt1+2,xxx1+2,fnt_def1+2: first_par:=get_three_bytes; right1,w1,x1,down1,y1,z1: first_par:=signed_byte; right1+1,w1+1,x1+1,down1+1,y1+1,z1+1: first_par:=signed_pair; right1+2,w1+2,x1+2,down1+2,y1+2,z1+2: first_par:=signed_trio; set1+3,set_rule,put1+3,put_rule,right1+3,w1+3,x1+3,down1+3,y1+3,z1+3, fnt1+3,xxx1+3,fnt_def1+3: first_par:=signed_quad; nop,bop,eop,push,pop,pre,post,post_post,undefined_commands: first_par:=0; w0: first_par:=w; x0: first_par:=x; y0: first_par:=y; z0: first_par:=z; sixty_four_cases(fnt_num_0): first_par:=o-fnt_num_0; end; end; @ Here is the |do_dvi_commands| procedure. @p procedure do_dvi_commands; label 9999; var o:eight_bits; {operation code of the current command} @!p,@!q:integer; {parameters of the current command} @!cur_font:integer; {current internal font number} begin if (cur_fbase; 9999: do_nothing; end; @ The multiway switch in |first_par|, above, was organized by the length of each command; the one in |do_dvi_commands| is organized by the semantics. @ @= begin o:=get_byte; p:=first_par(o); if eof(dvi_file) then bad_dvi('the DVI file ended prematurely'); @.the DVI file ended prematurely@> if omax_fnums then if vf_reading then abort('no font selected for character ',p:1,' in virtual font') else bad_dvi('no font selected for character ',p:1); @.no font selected@> set_virtual_char(cur_font,p); h:=h+@; end else case o of four_cases(put1): set_virtual_char(cur_font,p); set_rule: begin q:=trunc(signed_quad*dvi_scale); do_set_rule(trunc(p*dvi_scale),q); h:=h+q; end; put_rule: do_set_rule(trunc(p*dvi_scale),trunc(signed_quad*dvi_scale)); @t\4@>@@; undefined_commands:bad_dvi('undefined command ',o:1); @.undefined command@> end; {all cases have been enumerated} end @ @= four_cases(xxx1): for k:=1 to p do down_the_drain:=get_byte; pre,post,post_post: bad_dvi('preamble or postamble within a page!'); @.preamble or postamble within a page@> @ @= nop: do_nothing; bop: bad_dvi('bop occurred before eop'); @.bop occurred before eop@> eop: goto 9999; push: do_push; pop: do_pop; @ @= four_cases(right1):h:=h+trunc(p*dvi_scale); w0,four_cases(w1):begin w:=trunc(p*dvi_scale); h:=h+w; end; x0,four_cases(x1):begin x:=trunc(p*dvi_scale); h:=h+x; end; four_cases(down1):v:=v+trunc(p*dvi_scale); y0,four_cases(y1):begin y:=trunc(p*dvi_scale); v:=v+y; end; z0,four_cases(z1):begin z:=trunc(p*dvi_scale); v:=v+z; end; @ @= sixty_four_cases(fnt_num_0),four_cases(fnt1): cur_font:=select_font(p); four_cases(fnt_def1): define_font(p); @* The main program. Now we are ready to put it all together. This is where \.{DVItoMP} starts, and where it ends. @p begin initialize; {get all variables initialized} @; open_mpx_file; print_ln(banner); begin while true do begin @; for k:=0 to 10 do down_the_drain:=signed_quad; @; start_picture; do_dvi_commands; if stk_siz<>0 then bad_dvi('stack not empty at end of page'); @.stack not empty...@> stop_picture; print_ln('mpxbreak'); end; done:end; final_end:end. @ The main program needs a few global variables in order to do its work. @= @!k,@!p:integer; {general purpose registers} @!numerator,@!denominator:integer; {stated conversion ratio} @ @= open_dvi_file; p:=get_byte; {fetch the first byte} if p<>pre then bad_dvi('First byte isn''t start of preamble!'); @.First byte isn't...@> p:=get_byte; {fetch the identification byte} if p<>id_byte then warn('identification in byte 1 should be ',id_byte:1,'!'); @.identification...should be n@> @; p:=get_byte; {fetch the length of the introductory comment} while p>0 do begin decr(p); down_the_drain:=get_byte; end @ The conversion factor |conv| is figured as follows: There are exactly |n/d| decimicrons per \.{DVI} unit, and 254000 decimicrons per inch, and |resolution| pixels per inch. Then we have to adjust this by the stated amount of magnification. No such adjustment is needed for |dvi_per_fix| since it is used to convert design sizes. @= numerator:=signed_quad; denominator:=signed_quad; if (numerator<=0)or(denominator<=0) then bad_dvi('bad scale ratio in preamble'); @.bad scale ratio@> mag:=signed_quad/1000.0; if mag<=0.0 then bad_dvi('magnification isn''t positive'); @.magnification isn't positive@> conv:=(numerator/254000.0)*(72.0/denominator)*mag; dvi_per_fix:=(254000.0/numerator)*(denominator/72.27)/1048576.0; @ @= repeat k:=get_byte; if (k>=fnt_def1)and(knop; if k=post then goto done; if k<>bop then bad_dvi('missing bop'); @.missing bop@> @* System-dependent changes. This section should be replaced, if necessary, by changes to the program that are necessary to make \.{DVItoMP} work at a particular installation. It is usually best to design your change file so that all changes to previous sections preserve the section numbering; then everybody's version will be consistent with the printed program. More extensive changes, which introduce new sections, can be inserted here; then only the index itself will get a new section number. @^system dependencies@> @* Index. Pointers to error messages appear here together with the section numbers where each ident\-i\-fier is used.