ack/mach/m68k2
1985-04-12 15:47:30 +00:00
..
cg floating point stuff added 1985-04-12 15:47:30 +00:00
dl fixup commit for tag 'dist2' 1985-02-17 00:57:20 +00:00
libbc fixup commit for tag 'dist2' 1985-02-17 00:57:20 +00:00
libcc fixup commit for tag 'dist2' 1985-02-17 00:57:20 +00:00
libem Added .align 2. Prevents end of bss to be odd. 1985-02-17 01:12:36 +00:00
libpc fixup commit for tag 'dist2' 1985-02-17 00:57:20 +00:00
libsys Argument is 4 bytes (pointer), not 2 bytes. 1985-03-05 12:33:29 +00:00
ncg fixup commit for tag 'dist2' 1985-02-17 00:57:20 +00:00
Action The dl programs is replaced by a more general cv. 1985-03-26 16:20:11 +00:00
README fixup commit for tag 'dist2' 1985-02-17 00:57:20 +00:00
Unisoft_bug *** empty log message *** 1985-04-09 13:48:55 +00:00

The m68k2 back end is an EM code generator for the
Motorola MC68000. It defines an integer to be 16 bits
and a pointer to be 32 bits.
At present it does not support floating point operations.
(All EM floating point instructions are translated to the
68000 "trap" instruction.)
The m68k2 back end generates code for the ACK 68000 assembler/linker.
(The mnemonics recognized by this assembler can be found in
"as/mach3.c"). As this assembler/linker does not define an
object (.o) format, it can only link assembly files. Consequently,
all library modules are stored as assembly files.

Some parts of the back end are system dependent, i.e. they depend
on the kind of target 68000 system.
   -	The way to do a Unix system call may vary from system to system.
	For every system call you need to have an assembly routine that
	passes the arguments and the system call number to Unix.
	These routines should be put in the library file "lib/tail_mon".
	The distribution contains a tail_mon file tailored for
	UniSoft Unix (see directory "libsys").
	Beware that several Unix systems (e.g. UniSoft Unix) use 4-byte
	integers, whereas the m68k2 back end produces code for 2-byte
	integers. In this case all system calls having an "int" parameter
	should convert their parameters to "long"s.
   -	Most systems require some sort of "test for enough stack space"
	at the beginning of every procedure, to get around the "back up"
	problem. E.g. UniSoft Unix requires a "tst.b N(sp)" instruction
	This instruction is generated by the routines "prolog()" and
	"save" in "cg/mach.c".
   -	The output of the ACK 68000 assembler/linker is an a.out file that
	has a different format as an a.out file on your system. (As most
	68000 systems have different a.out formats, there is no such thing
	as "the" 68000 a.out format). So a program is needed to convert the
	ACK a.out format (i.e. a series of "emitrecs" as defined in
	"as/frame.c") to your a.out format (as defined in
	"/usr/include/a.out.h"). The 1-page program "dl/cv.c" does
	the job for UniSoft Unix. It probably need only be slightly
	modified for your system. Note that the program
	generates no text or bss segments, but only a data segment.
	If your target 68000 does not run Unix, but is e.g. a stand alone
	68000, you will need a program to download the ACK a.out file.
	The program "dl/dl.c" produces Intel Hex format on standard output
	from an a.out file.
   -	The EM runtime start-off ("libem/head_em.s") may have to be modified.
	It should call the procedure _m_a_i_n with parameters (argc,argv,envp).
	Usually, Unix will put these on top of the stack before starting
	the program. Note, however, that for 4-byte systems Unix will provide
	a 4-byte argc, while _m_a_i_n expects a 2-byte argc; so the value
	must be shortened to 2 bytes.
	The head_em also does a brk() system call to allocate the bss.
	(The size of the bss cannot be obtained from an ACK a.out file).


The m68k2 code generator translates most EM instructions in line.
For some complex EM instructions it uses assembly routines (stored in the
library "libem/libem_s.a").

The generated code does not check for array bound errors, overflow in
arithmetic operations or division by zero (the latter will cause a hardware
trap).

The code generator has the following register conventions:
	a7:		stack pointer
	a6:		local base pointer
	a0,a1,d0,d1,d2:	scratch registers
			(d0 is also used for 2/4 bytes function results;
			 d0 and d1 are used for 8 bytes function results)
	a2-a5,d3-d7:	register variables.