Provided by: zmakebas_1.2-1.1_amd64 bug

NAME

       zmakebas - convert text file into Spectrum Basic program

SYNOPSIS

       zmakebas  [-hlr]  [-a startline] [-i incr] [-n speccy_filename] [-o output_file] [-s line]
       [input_file]

DESCRIPTION

       zmakebas converts a Spectrum Basic program written as a text file into  an  actual  speccy
       Basic  file (as a .TAP file, or optionally a raw headerless file). By default, input comes
       from stdin, and output goes to `out.tap'.

       Using zmakebas rather than (say) writing the Basic in an  emulator  means  you  can  write
       using a nicer editor, and can use tools which work on text files, etc. Also, with the `-l'
       option you can write without line numbers, using labels in their place where necessary.

       The program was originally intended to be used simply to make little loader  programs,  so
       they  wouldn't have to be sourceless binaries.  However, I went to a fair amount of effort
       to make sure it'd work for bigger, more serious programs too, so you can also use  it  for
       that kind of thing.

OPTIONS

       -a     make  the  generated  file  auto-start from line startline.  If `-l' was specified,
              this can be a label, but don't forget to include the initial `@' to point this out.

       -h     give help on command line options.

       -i     in labels mode, set line number increment (default 2).

       -l     use labels rather than line numbers.

       -n     specify filename to use in .TAP file (up to 10 chars), i.e. the filename the speccy
              will see. Default is a blank filename (10 spaces).

       -o     output to output_file rather than the default `out.tap'. Use `-' as the filename to
              output on stdout.

       -r     write a raw headerless Basic file, rather than the default .TAP file.

       -s     in labels mode, set starting line number (default 10).

INPUT FORMAT

       The input should be much as you would type into a speccy (a 128, to be precise), with  the
       following exceptions:

       Lines  starting  with  `#'  are  ignored. This allows you to insert comments which are not
       copied into the output Basic file.

       Blank lines are ignored.

       Case is ignored in keywords - `print', `PRINT', and `pRiNt' are equivalent.

       You can optionally use `randomise' as an alternative to `randomize'.

       You can get hex numbers by using `bin' with a C-style hex number, e.g.  to get 1234h you'd
       use `bin 0x1234'. (It appears in exactly that form in the speccy listing, though, so don't
       use it if you want to be able to edit the output program on a speccy.)

       You can get a pound sign (character 96 on a speccy) by using a backquote (`).

       One input line normally equals one line of Basic, but you can use backslash  as  the  last
       character of a line to continue the statement(s) on the next input line.

       Rather  than  literally  inserting  block  graphics  characters and UDGs as you would on a
       speccy, you should use an escape sequence. These begin with a backslash (`\').  To  get  a
       UDG,  follow  this  backslash  with the UDG's letter, in the range `a' to `u' (`t' and `u'
       will only have the desired effect if the program is run on a 48k speccy or  in  48k  mode,
       though);  both  upper and lowercase work. To get the copyright symbol, follow it with `*'.
       To get a block graphics character, follow it with a two-character `drawing'  of  it  using
       spaces, dots, apostrophes and/or colons. (For example, you'd get character 135 with `\':',
       and character 142 with `\:.'.) To get a literal `@', follow it with `@'.  (This is  needed
       only  if the `-l' option was given, but works whether it was or not.) To specify a literal
       eight-bit character code to dump into the Basic output file directly (to use for  embedded
       colour  control  codes  and  the like), use braces and a C-syntax number e.g.  `\{42}' for
       decimal, and `\{0x42}' for hex. Finally, as usual with such things, you can get a  literal
       backslash by following the first backslash with another.

       If  the  `-l'  option  was  given,  line  numbers  must  be  omitted.  Instead  these  are
       automatically generated in  the  output,  and  you  can  use  labels  where  necessary  as
       substitute  line  numbers  for  `goto'  commands  etc.  A  label  is defined with the text
       `@label:' at the beginning of a line (possibly preceded by whitespace). It can be referred
       to  (before  or  after)  with `@label'. Any printable ASCII character other than colon and
       space can be used in a label name. Here's an example of how labels work, showing both  the
       input and (listing of) the output - first, the input:

       goto @foo
       print "not seen"
       @foo: print "hello world"

       Now the output:

       10 GO TO 14
       12 PRINT "not seen"
       14 PRINT "hello world"

       Note that case is significant for labels; `foo' and `FOO' are different.

BUGS

       There's almost no syntax checking. To do this would require a complete parser, which would
       be overkill I think. What's wrong with ``C Nonsense in BASIC'' as a syntax check,  anyway?
       :-)

       Excess  spaces  are  removed  everywhere other than in strings and rem statements. I think
       this is generally what you'd want, but it could be seen as a bad thing I s'pose.

       Labels are substituted even in string literals. That's arguably a feature not a bug -  the
       problem  is,  the  label  name  has  to  be  followed by whitespace or a colon or EOL when
       referenced, which is fine for more normal references but is less than ideal for references
       in strings.

       In the label-using mode, two passes are made over the input, which usually means the input
       must be from a file. If you like making one-liner Basic programs with `echo' and the like,
       I'm afraid you'll have to use line numbers. :-)

       The  inline  floating-point  numbers which have to be generated are not always exactly the
       same as the speccy would generate - but they usually are, and even when  they're  not  the
       difference is extremely small and due to rounding error on the speccy's part. For example,
       0.5 is encoded  by  the  speccy  as  7F  7F  FF  FF  FF  (exponent  -1,  mantissa  approx.
       0.9999999997672) and by zmakebas as 80 00 00 00 00 (exponent 0, mantissa 0.5).

       zmakebas  has  most of the same (parsing) problems, relative to the original basic editor,
       that the 128 editor has. Specifically, you can't  use  variable  names  which  clash  with
       reserved  words,  so e.g. `ink ink' doesn't work; and certain tightly-packed constructions
       you might expect to work, like `chr$a', don't (you need a space or  bracket  after  CHR$).
       These can be more of a problem with zmakebas though, due to the lack of syntax checking.

       The  way  tokenisation is done is sub-optimal, to say the least. If you ran this code on a
       Z80, even the 128 editor's tokenisation would seem quick in comparison. (Here's a hint  of
       the  full  horror  of  it - program lines take exponentially longer to tokenise the longer
       they are.)  However, since I never had a conversion take more than about a  second  on  my
       old 486 (it took a second for a 10k program), it hardly seems worth the effort of fixing.

       zmakebas  has  no  problem  with  translating BIN numbers of more than 16 bits, unlike the
       speccy, though numbers with more than 32 significant bits can only be approximated, and on
       machines  where  `unsigned  long' is no more than 32 bits they'll be very approximate. :-)
       (If this sounds confusing, you should note that BIN numbers are translated  when  entered,
       and  only  the  5-byte  inline  form  is dealt with at runtime. This also explains why the
       speccy tolerates the `bin 0x...' construction.)

       On machines without FP hardware, zmakebas will be rather slow (this is due to the need  to
       generate inline FP numbers).

       Since Basic is an acronym, pedants will doubtless insist I should write it as `BASIC'. But
       we live in a world with `laser' etc., and at least I can be  bothered  to  capitalise  the
       thing, right? :-)

SEE ALSO

       fuse(1), xz80(1), xzx(1)

AUTHOR

       Russell Marks (russell.marks@ntlworld.com).