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.macro
The commands .macro
and .endm
allow you to define macros that
generate assembly output. For example, this definition specifies a macro
sum
that puts a sequence of numbers into memory:
.macro sum from=0, to=5 .long \from .if \to-\from sum "(\from+1)",\to .endif .endm
With that definition, ‘SUM 0,5’ is equivalent to this assembly input:
.long 0 .long 1 .long 2 .long 3 .long 4 .long 5
.macro
macname.macro
macname macargs ...
req
’), or whether it takes all of the remaining arguments
(through ‘:vararg
’). You can supply a default value for any
macro argument by following the name with ‘=deflt’. You
cannot define two macros with the same macname unless it has been
subject to the .purgem
directive (see Purgem) between the two
definitions. For example, these are all valid .macro
statements:
.macro comm
comm
, which takes no
arguments.
.macro plus1 p, p1
.macro plus1 p p1
plus1
,
which takes two arguments; within the macro definition, write
‘\p’ or ‘\p1’ to evaluate the arguments.
.macro reserve_str p1=0 p2
reserve_str
, with two
arguments. The first argument has a default value, but not the second.
After the definition is complete, you can call the macro either as
‘reserve_str a,b’ (with ‘\p1’ evaluating to
a and ‘\p2’ evaluating to b), or as ‘reserve_str
,b’ (with ‘\p1’ evaluating as the default, in this case
‘0’, and ‘\p2’ evaluating to b).
.macro m p1:req, p2=0, p3:vararg
m
, with at least three
arguments. The first argument must always have a value specified, but
not the second, which instead has a default value. The third formal
will get assigned all remaining arguments specified at invocation time.
When you call a macro, you can specify the argument values either by position, or by keyword. For example, ‘sum 9,17’ is equivalent to ‘sum to=17, from=9’.
Note that since each of the macargs can be an identifier exactly
as any other one permitted by the target architecture, there may be
occasional problems if the target hand-crafts special meanings to certain
characters when they occur in a special position. For example, if the colon
(:
) is generally permitted to be part of a symbol name, but the
architecture specific code special-cases it when occurring as the final
character of a symbol (to denote a label), then the macro parameter
replacement code will have no way of knowing that and consider the whole
construct (including the colon) an identifier, and check only this
identifier for being the subject to parameter substitution. So for example
this macro definition:
.macro label l \l: .endm
might not work as expected. Invoking ‘label foo’ might not create a label called ‘foo’ but instead just insert the text ‘\l:’ into the assembler source, probably generating an error about an unrecognised identifier.
Similarly problems might occur with the period character (‘.’) which is often allowed inside opcode names (and hence identifier names). So for example constructing a macro to build an opcode from a base name and a length specifier like this:
.macro opcode base length \base.\length .endm
and invoking it as ‘opcode store l’ will not create a ‘store.l’ instruction but instead generate some kind of error as the assembler tries to interpret the text ‘\base.\length’.
There are several possible ways around this problem:
Insert white space
.macro label l \l : .endm
Use ‘
\()’
.macro opcode base length \base\().\length .endm
Use the alternate macro syntax mode
.altmacro .macro label l l&: .endm
Note: this problem of correctly identifying string parameters to pseudo ops
also applies to the identifiers used in .irp
(see Irp)
and .irpc
(see Irpc) as well.
.endm
.exitm
\@
LOCAL
name [ , ... ]
LOCAL
is only available if you select “alternate
macro syntax” with ‘--alternate’ or .altmacro
.
See .altmacro
.