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xa65/xa/doc/fileformat.txt
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6502 binary relocation format
V1.2 as of 26jan1998
(c) André Fachat (a.fachat@physik.tu-chemnitz.de)
_________________________________________________________________
Changes from V1.1
The order for saving the undefined reference and the low byte of a
high byte relocation entry has changed. This makes the OS/A65 lib6502
implementation easier. How many other people use this format
anyway...?
_________________________________________________________________
0) Preface
With some new 6502/C64/C128 operating systems comes the need for a new
binary format. In multitasking operating systems like Lunix, SMOS, or
OS/A65, a binary file cannot be loaded to a fixed location that might
already be used by another program. Therefore it must be possible to
relocate the program to an arbitrary address at least at load time. In
addition to that, more specific information might be stored in a
binary executable file, like interrupt vectors for example.
This text gives a good solution to this problem for the 6502 CPU and
an assembler source format to use this format in a general manner. The
file format can even be used as an object file format, i.e. a format a
linker can use as an input file. It is also usable as a 65816 file
format. Instead of zeropage addressing modes, the 65816 has direct
addressing modes, that add the contents of the direct register to the
zeropage address in the opcode.
1) 6502/65816 specifics
The 6502 has the special feature of a 'zeropage', i.e. a very limited
memory address range used for special addressing modes. So the format
should not only provide a means to relocate absolute addresses but
also zeropage addresses. The 65816 replaces zeropage addressing with
direct addressing modes.
The stack space is also very limited. A binary format has to provide a
measure of how much stack space is needed for the application.
Such limits should be defined as 2 byte values, even if the 6502 only
has a range of 8 address bits for zeropage and stack. But the 65816
behaves differently, it has a 16 bit stack pointer for example. For
further expandability, a 32 bit format should be provided, although
the 16 bit format suffices for the 65816 already.
Another problem is, that an address can be 'split', i.e. you can just
use the high byte or the low byte separately in an opcode. This gives
need to a special relocation table format, that can cope with
half-address references. The 65816 can even have three byte addresses,
i.e. address in a segment and segment number.
2) binary format
2.1) General
The file differs from the known Commodore file formats, in that a lot
more information is stored in the file. First the data is structured
in separate segments to allow different handling of text (program
code), data (like tables) and bss (uninitialized data).
Also tables are included to allow late binding, i.e. linking the file
with other files at load time, and relocation, i.e. executing the file
at different addresses in 6502 address space.
2.2) Segments
As already used in other formats, the assembler uses three different
segment types, i.e. text (the actual program code), data (initialized
variables), and bss (uninitialized variables). To have these different
segments seems to be 'overdesigned', but they actually make memory
handling easier in more complex operating systems on systems with
virtual addresses (OS/A65, for example).
The text segment is defined to be read-only memory. This doesn't allow
self-modifying code in this segment, but allows memory sharing in
virtual memory architectures. The data segment actually is like the
text segment, only it is allocated writable. This segment might not be
shared between different processes. The contents of these two segments
are loaded from the file. The bss segment is uninitialized data, i.e.
upon program start, it is not defined - and not loaded from the file.
This area is read-write and can be used during program execution. It
is also not shared between processes. In addition to these segments,
the 6502 format also includes a zeropage segment type, to allow
zeropage variables to be relocated. This zeropage segment is like a
bss segment, in that only the length, but not the data is saved. For
the 65816 the zeropage segment changes its meaning to a bank zero
segment.
The different segments hold different type of data and can be located
anywhere in memory (except zero segment, which has to be in the
zeropage resp. bank zero). The program must therefore not assume
anything about the relative addresses between different segments.
2.3) Relocation
In general, there are three ways to handle the relocation problem so
far:
- Tables: have a relocation table for a text segment
if the relocation table is put in front of code
you have to save the table in a side-storage
if table is behind, you still cannot relocate 'on the fly'.
- Deassembling: go through the code, deassemble it and change all absolute
addresses. Problem: needs to know or have hints about where some
data is in the code.
- Relocation info in the code: here each address is preceeded with an
'escape' code and is relocated when loading. But this disallows block
oriented transfer from storage media to memory.
This binary format uses the first method, with the table after the
code/data. This way block oriented transfer for the text/data segment
can be used. And while reading the relocation tables bytewise, the
relocation can be done without the need to save the table somewhere.
2.4) External References & Exported Globals
As this file format should not only be used as an executable format,
but also as object file format, it must provide a way to define
references - references exported from this object and labels
referenced in this object. The external references list (also called
'undefined list') lists the addresses where labels not defined in this
object are referenced. The exported globals list lists the addresses
that are available for other objects. The labels are named by
null-terminated ASCII strings.
Even an executable file can have non-empty globals and externals
lists, but only if the operating system allows this. In this case, so
called 'late binding' is used to link the object with some global
libraries at link time.
2.5) File extension
The proposed standard extension for the described format is ".o65"
when used as an object file.
2.6) Format description
The binary format is the following:
(
header
text segment
data segment
external references list
relocation table for text segment
relocation table for data segment
exported globals list
)
The description of the parts follows:
2.6.1) Header
The header contains the minimum needed data in a fixed struct. The
rest of the necessary information is put into the header options.
[Note: .word is a 16 bit value, low byte first, .byt is a simple byte.
.long is a 32 bit value, low byte first. .size is a 16 or 32 bit value
according to .word and .long, depending on the size bit in the mode
field ]
This is the fixed struct:
(
.byt $01,$00 ; non-C64 marker
.asc "o65" ; o65 MAGIC!
.byt 0 ; version
.word mode ; mode word
.size tbase ; address to which text is assembled to
; originally
.size tlen ; length of text segment
.size dbase ; originating address for data segment
.size dlen ; length of data segment
.size bbase ; originating address for bss segment
.size blen ; length of bss segment
.size zbase ; originating address for zero segment
.size zlen ; length of zero segment
.size stack ; minimum needed stack size, 0= not known.
; the OS should add reasonable values for
; interrupt handling before allocating
; stack space
)
The mode word currently has these defined bits:
mode.15 : CPU 0= 6502 1= 65816
mode.14 : reloc 0= bytewise... 1= page(256byte)wise relocation
allowed
mode.13 : size 0= size=16 bit, 1= size=32 bit
mode.12 : obj 0= executable 1= object file
mode.0-1: align 0= byte align,
1= word (i.e. 2 byte) align
2= long (4 byte) align
3= block (256 byte) align
The CPU bit tells the loader for which CPU the file was made. This has
implications on the zero segment, for example. Also a system can check
if the program will run at all (on a 6502 that is). The reloc bit
defines if an object file can be relocated bytewise, or if it must be
page-aligned. A page has 256 bytes. The restriction to pagewise
relocation simplifies the relocation table and also allows simpler
compilers/assemblers. The size bit determines the size of the segment
base address and length entries. Currently the 16 bit size (size bit =
0) works for 6502 and 65816 CPUs.
The obj bit distinguishes between object files and executables. An
object file is used as assembler output that can be linked with other
object files to build an executable or an object library. The two
align bits give the address boundary the segments can be placed. Even
the 6502 needs this, as, for example, "jmp ($xxFF)" is broken. The
align bits are valid for all of the segments. [Note: if reloc=1, then
align should be 3. But if align=3, reloc need not be 1, because reloc
switches to a simpler version of the relocation table. The reloc bit
might be obsoleted in newer versions of this format. Though it should
be set, if necessary.]
All unused bits in the mode field must be zero.
Note that the header size is 26 if the size bit is zero and 44 if the
size bit is one.
The fixed sized struct is immediately followed by a list of header
options. Each header option consists of a single byte total length, a
type byte and some data bytes if needed. A single length byte of $00
ends the header option list.
(
{ ; optional options, more than one allowed
.byt olen ; overall length (including length and type
; byte
.byt otype ; option type
[ .byt option_bytes ]
}
.byt $00 ; end of options marker (i.e. option len=0)
)
The header options currently defined/proposed are:
- Filename:
type=0; len=strlen(filename_in_ascii)+3; content="filename_in_ascii",0
The string contains the name of the object.
- Operating System Header
type=1; len=?
the first data byte is the OS type:
1 OSA/65 header supplement
2 Lunix header supplement
[others to follow?]
the following data contains OS specific information.
A suggested data byte is the OS version as second byte.
- Assemblerprogram:
type=2; len=strlen(ass)+3; content="ass",0
The string contains the name of the assembler resp. linker that produced
this file/object.
For example (syntax see below)
.fopt 2, "xa 2.1.1g",0
becomes
0c 02 78 61 20 32 2e 31 2e 31 67 00
in the file.
- Author:
type=3; len=strlen(author)+3; content="author",0
The string contains the author of the file.
- Creation data:
type=4; len=strlen(date)+3; content="date_string",0
The string contains the creation date in format like:
"Sat Dec 21 14:00:23 MET 1996", where we have the day, Month, date,
time, timezone and year. See output of `date`...
2.6.2) text and data segments
The text and data segments are just the assembled code. The only
difference between text and data segments is the read/write mode of
the two segments. Therefore, to be compliant to this file format,
self-modifying code goes into the data segment.
2.6.3) Undefined references list
The next list is an ASCII list of labels that are referenced in this
file but not defined. The lists is preceeded with the number of
undefined labels (16 or 32 bits, according to the mode.size bit).
undef_list: number_of_undefined_labels.s
"undefined_label1",0
"undefined_label2",0
...
2.6.4) Relocation tables
The relocation tables are the same format for the two segments, text
and data. In general a relocation entry consists of the offset from
the previous relocation address to the next one, the type of the
relocation and additional info. Relocation not only defines the
relocation when moving object code to a different address, but also
filling in the undefined references.
Each table starts at relocation address = segment base address -1.
I.e. if the segment base address is $1000 for example, the first entry
has an offset computed from base address-1 = $0fff. The offset to the
next relocation address is the first byte of each entry. If the offset
is larger than 254 (i.e. 255 or above), than a 255 is set as offset
byte, the offset is decremented by 254 (note the difference) and the
entry is started again.
{ [255,...,255,] offset of next relocation (b), typebyte|segmentID [, low_byte]
}+
where typebyte has the bits 5, 6 and 7 and is one of
WORD $80 2 byte address
HIGH $40 high byte of an address
LOW $20 low byte of an address
SEGADR $c0 3 byte address (65816)
SEG $a0 segment byte of 3 byte address
The segmentID stands for the segment the reference points to:
0 undefined
1 absolute value
2 text segment
3 data segment
4 bss segment
5 zero segment
(Of course the absolute value will never appear in a relocation table,
but this value is necessary for the exported list)
If the type is HIGH, the low byte of the value is stored behind the
relocation table entry, if bytewise relocation is allowed (header mode
field bit 14). If only pagewise relocation is allowed, then only HIGH
relocation entries can occur, and the low byte is implicitely set zero
(i.e. it is _not_ saved in the relocation table).
If the type is SEG, then the two lower bytes of the three byte segment
address are stored behind the entry in the relocation table, lower
byte first.
If the segment is "undefined", the typebyte is immediately followed by
the two (mode size=0) or four (mode size=1) byte value index in the
undefined references list. If it is a high byte relocation, the low
byte is saved behind the index value. The index value determines the
undefined reference, which must be looked up by the loader.
The value taken from the relocation address in the segment, together
with the low byte from the relocation table (if HIGH entry) form the
address used if the segment would be used unrelocated. To relocate the
segment, the difference between the relocated segment base address and
the segment base address from the file is then added to the above
address. The result is again saved in the segment.
A zero offset byte ends the relocation table. The first offset is
computed from the segment base address-1, to avoid a 0 value in the
first entry.
Note that direct addressing modes do not generate entries in the
relocation table. instead it is assumed that the 65816 direct register
holds the correct value (i.e. zero segment base address) when running
this program.
Example:
Segment Base address in file (header.tbase) is $1000. The start
address of the text segment after relocation is real.tbase = $1234.
Now the first (unrelocated) address at which a relocation should take
place is here:
$1222 A9 23 lda #>vector
This generates the offset: $1222-($1000-1) = $223. This is larger than
254 ($fe), so the first byte is 255 ($ff). The offset is decremented
by $fe, and gives $125. This again is larger than $fe, so the next
byte is $ff again. After substracting $fe again, we have $27. But this
is the address of the opcode. To get the address of the address byte,
we have to add 1 to get $28, which becomes the third byte. The next
offset is then computed from $1223, because this is the last
relocation address.
Now we reference the high byte of an address, lets say vector=$23d0
(not relocated), in the text segment. Therefore the relocation type
becomes 'HIGH | text_segmentID = $42', which is the next byte. Because
we are referencing a high byte of an address, the low byte of the
unrelocated address is saved behind the typebyte in the relocation
entry. This byte is missing when referencing a low byte or address.
The relocation table entry is now:
$ff, $ff, $28, $42, $d0.
When actually doing the relocation, the relocation pointer is
initialized to real.tbase-1 = $1233. Then we compute the offset to
$224, which brings us to $1457, where the address byte of the above
opcode is after loading the file to $1234. We now have to compute the
new address, where vector is after relocation. So we take the
unrelocated low byte from the relocation table ($d0) and the high byte
from $1457 ($23).
vector_file = ($23
To this value we add
the difference between the address the program is assembled to and the
real load address:
vector_relocated = vector_file + (real.tbase - header.tbase)
= $23d0 + ($1234 - $1000)
= $23d0 + $234
= $2604
From this value the high byte is then written back to the address $1457.
Had we not saved the low byte in the relocation table, and only added
the high bytes, we would have missed the carry bit that increments
the high byte in this case!
Had "vector" now been an undefined reference, and "vector" would be
the second label in the undefined references list, we would get the
following relocation table entry (assuming mode.size=0):
$ff, $ff, $28, $40, $00, $02, $00
The value computed with the above formula for vector_file is now added
to the address the label "vector" now really has (This must of course
be looked up into an external table or list).
Had the opcode been "LDA #>vector+$567", then the low byte in the relocation
table would be $67, while the high byte in the opcode would be $05.
This value would result in vector_file and the real address of "vector"
would be added before wrting back the high byte to the opcode.
2.6.5) exported globals list
The global list is a list of names, together with the target segment
and the offset in the segment for each name. It is preceeded with the
number of exported labels. This allows the loader to allocate a table
large enough, if needed. The number of labels and the offset value
are 16 bit or 32 bit values according to the size bit in the header mode
field. The segmentID is a byte value and the same as in the relocation
table entry (see section 2.6.3).
number_of_exported_labels.s
"global_label_name_in_asc1",0, segmentID.b, value.s
...
3) assembler source format
The assembler source format is a suggestion only. It will be implemented
in xa65, a cross assembler for 6502 CPUs running on Unix/Atari ST/Amiga
as a reference platform.
The assembler provides a way to embed absolute address code in relocatable
code. This is needed when code should be copied to a specific location
known at assemble time.
There also is a way to make a file 'romable'. You can give the start
address of the _file_ in ROM, and the assembler automatically sets
the text segment start address to where the code will be in the ROM.
Of course, the other segments must be taken care of with -b? command
line parameter, that set the segment start address.
3.1) embed absolute code in relocatable files
When the assembler is started in relocatable mode, everything is put into
a .o65 relocatable file. All address references generate relocation table
entries. If a "*= value" pseudo opcode is encountered,
then the assembler switches to absolute mode. The following opcodes don't
generate relocation table entries. If a "*=" without a value is read,
then the assembler switches back to relocatable mode. The relocation
program counter is increased with the length of the absolute part and
the absolute code is embedded between the relocatable parts.
3.2) embed relocatable code in absolute files
This is dropped - too complicated. Should better be done with some
objdump or linker programs or so.
3.2) Header options
Before any opcode (after starting in relocatable mode, or after a .reloc
opcode), a header option can be set by:
.fopt byte1, byte2, ...
The header option length is automatically set by the assembler.
An example for an file author entry:
.fopt 3, "Andre Fachat",0
The 3 is the type byte for the author header option. The last zero ends
the name. The assembler can be configured to automatically include an
assembler header option into a file header.
3.3) allocation of data segment/zeropage segment address space
The assembler switches between the different segments by the means of
".text", ".data", ".bss" and ".zero" pseudo opcodes. After starting in
relocatable mode, the assembler is in the text segment.
The text segment contains the program code. Data holds the initialized data,
while bss and zero segments contain uninitialized data for normal/zeropage
address space.
Everything that is between one of these segment opcodes and the next segment
opcode gets into the corresponding segment, i.e. labels, assembled code etc.
The text and data segments are saved in the file, while for the bss and
zero segments only the length is saved in the file.
The assembler should issue a warning when a direct addressing mode
is used without a zero segment address and vice versa for 65816 CPUs.
3.4) referencing data/bss/zeropage addresses
One problem with the 6502 is, that it cannot load an address within one
step or assembler opcode. So an address is loaded with standard byte
opcodes, like "lda #
The assembler is now intelligent enough to evaluate such expressions
and check for:
- no address label : ok, absolute
- one address label, only add to label : ok, relocate
- difference between two addresses : If addresses in same segment, compute
diff and set absolute, otherwise bail
- everything else : warning
This way there is no change in syntax. Address labels are distinguished
by using the "label:" syntax, as opposed to "label = value".
Also, if the assembler is capable of doing so, an address label may be
defined by "label opcode", i.e. without a colon.
3.5) aligning code
The 6502 has the problem that some opcodes (e.g. "JMP ($xxFF)" are
broken, if the address given is at some (odd) address. But when loading
a relocatable file, one cannot know if an address will be odd or even.
Therefore there is a new opcode,
.align 2
that aligns the next address at the given address boundary. Valid
values are 2, 4, and 256.
4) Clearance
This file is surely not the optimum and could be improved. Also the
header option "assigned numbers" should be added here.
For this reason the author, André Fachat, will function as a
clearing point, where problems can be discussed and number can be assigned.
Dec. 22, 1996,
André Fachat
(fachat@physik.tu-chemnitz.de)
Appendix
A) File examples
(to be done with reference assembler)