LOC
LOC
directive sets the current location to the value of the
operand field, which may include changing sections. If the operand is a
constant, the section is set to either .data
if the value is
0x2000000000000000
or larger, else it is set to .text
.
Within a section, the current location may only be changed to
monotonically higher addresses. A LOC expression must be a previously
defined symbol or a “pure” constant.
An example, which sets the label prev to the current location, and updates the current location to eight bytes forward:
prev LOC @+8
When a LOC has a constant as its operand, a symbol
__.MMIX.start..text
or __.MMIX.start..data
is defined
depending on the address as mentioned above. Each such symbol is
interpreted as special by the linker, locating the section at that
address. Note that if multiple files are linked, the first object file
with that section will be mapped to that address (not necessarily the file
with the LOC definition).
LOCAL
LOCAL external_symbol LOCAL 42 .local asymbol
This directive-operation generates a link-time assertion that the operand
does not correspond to a global register. The operand is an expression
that at link-time resolves to a register symbol or a number. A number is
treated as the register having that number. There is one restriction on
the use of this directive: the pseudo-directive must be placed in a
section with contents, code or data.
IS
IS
directive:
asymbol IS an_expression
sets the symbol ‘asymbol’ to ‘an_expression’. A symbol may not be set more than once using this directive. Local labels may be set using this directive, for example:
5H IS @+4
GREG
areg GREG breg GREG data_value GREG data_buffer .greg creg, another_data_value
The symbolic register name can be used in place of a (non-special)
register. If a value isn't provided, it defaults to zero. Unless the
option ‘--no-merge-gregs’ is specified, non-zero registers allocated
with this directive may be eliminated by as
; another
register with the same value used in its place.
Any of the instructions
‘CSWAP’,
‘GO’,
‘LDA’,
‘LDBU’,
‘LDB’,
‘LDHT’,
‘LDOU’,
‘LDO’,
‘LDSF’,
‘LDTU’,
‘LDT’,
‘LDUNC’,
‘LDVTS’,
‘LDWU’,
‘LDW’,
‘PREGO’,
‘PRELD’,
‘PREST’,
‘PUSHGO’,
‘STBU’,
‘STB’,
‘STCO’,
‘STHT’,
‘STOU’,
‘STSF’,
‘STTU’,
‘STT’,
‘STUNC’,
‘SYNCD’,
‘SYNCID’,
can have a value nearby an initial value in place of its
second and third operands. Here, “nearby” is defined as within the
range 0...255 from the initial value of such an allocated register.
buffer1 BYTE 0,0,0,0,0 buffer2 BYTE 0,0,0,0,0 ... GREG buffer1 LDOU $42,buffer2
In the example above, the ‘Y’ field of the LDOUI
instruction
(LDOU with a constant Z) will be replaced with the global register
allocated for ‘buffer1’, and the ‘Z’ field will have the value
5, the offset from ‘buffer1’ to ‘buffer2’. The result is
equivalent to this code:
buffer1 BYTE 0,0,0,0,0 buffer2 BYTE 0,0,0,0,0 ... tmpreg GREG buffer1 LDOU $42,tmpreg,(buffer2-buffer1)
Global registers allocated with this directive are allocated in order
higher-to-lower within a file. Other than that, the exact order of
register allocation and elimination is undefined. For example, the order
is undefined when more than one file with such directives are linked
together. With the options ‘-x’ and ‘--linker-allocated-gregs’,
‘GREG’ directives for two-operand cases like the one mentioned above
can be omitted. Sufficient global registers will then be allocated by the
linker.
BYTE
WYDE
TETRA
OCTA
PREFIX
PREFIX a PREFIX b c IS 0
defines a symbol ‘abc’ with the value 0.
BSPEC
ESPEC
BSPEC 42 TETRA 1,2,3 ESPEC
The single operand to ‘BSPEC’ must be number in the range 0...255. The ‘BSPEC’ number 80 is used by the GNU binutils implementation.