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Complex datapath elements are usually comprised of arrayed versions of simpler cells. Although arrays can be created directly using arrayed instantiations, ACT supports looping constructs which can be a convenient way to create arrayed structures. More complex structures such as trees can be easily created using recursive instantiations.
An example of the loop construct in ACT is shown below:
( i : 10 : bool x[i..i]; )
i is the loop index and its scope is
delimited by the angle brackets. The colons separate the different parts
of the loop construct. The number
10 is an abbreviation for the
0..9. The body of the loop is the statement
bool x[i..i];. The effect of this statement is the same as
bool x[0..0]; bool x[1..1]; ... bool x[9..9];
The body of the loop can contain any ACT body, and therefore can have multiple statements in it. A more common use of the loop statement is shown below:
register r[1..8]; (i : 1..8 : r[i](in[i],out[i],control); )
In the example above, registers numbered
created. Their first two parameters are connected to the corresponding
elements of arrays
out. However, they have a shared
control that is passed in as the third parameter.
Since loops are part of ACT bodies, they can occur in the body of another loop. Thus, nested loops are also supported. However, types cannot be defined in the body of a loop.
A second more general looping construct is borrowed from the guarded command language.
pint i; i=0; *[ i < 10 -> bool x[i..i]; i = i + 1; ]
This builds an array element by element, using the guarded command
syntax for a general while loop. Note that in this case we are
i. This sort of construct can
only be used in the body of a type definition, since
are immutable in global scopes.
The first form of a loop is a special case of syntactic replication. The general loop syntax can include a separator, which is used in other contexts.
In production rule bodies, the loop
x & x & x
(notice the absence of a trailing
& is critical for the correct
& symbol separates the body of the loop that is
instantiated for different values of
Conditional execution is supported by the selection statement. The syntax of a selection statement is:
[ boolean_expression -> body  boolean_expression -> body .. ]
The last Boolean expression in the conditional can be the keyword
else, which is short-hand for 'all other guards are false.'
Any one body whose corresponding Boolean expression is true is executed. For instance, we can create 32 registers with something special for register 0 as follows:
(i : 32 : [ i = 0 -> r0(in[i],out[i],control)  else -> r[i](in[i],out[i],control) ] )
Boolean expressions can be constructed from Boolean variables, the
false, and the Boolean operators
~ denoting the and, or, and negation
operations respectively. Numeric expressions can be compared using
the operators less than, less than or equal to, greater than, greater
than or equal to, equal to, and not equal to respectively.