4.3.3 Array Aggregates
Syntax
Name Resolution Rules
The expected type for an
array_aggregate
(that is not a subaggregate) shall be a single array type.
The
component type of this array type is the expected type for each array
component expression of the
array_aggregate.
Legality Rules
An
others choice
is allowed for an
array_aggregate
only if an
applicable index constraint applies to the
array_aggregate.
An applicable index constraint is a constraint provided
by certain contexts where an
array_aggregate
is permitted that can be used to determine the bounds of the array value
specified by the aggregate. Each of the following contexts (and none
other) defines an applicable index constraint:
For an
explicit_actual_parameter,
an
explicit_generic_actual_parameter,
the
expression
of a return statement, the return expression of an expression function,
the initialization expression in an
object_declaration,
or a
default_expression
(for a parameter or a component), when the nominal subtype of the corresponding
formal parameter, generic formal parameter, function return object, expression
function return object, object, or component is a constrained array subtype,
the applicable index constraint is the constraint of the subtype;
For the operand of a
qualified_expression
whose
subtype_mark
denotes a constrained array subtype, the applicable index constraint
is the constraint of the subtype;
For a component
expression
in an
aggregate,
if the component's nominal subtype is a constrained array subtype, the
applicable index constraint is the constraint of the subtype;
For a parenthesized
expression,
the applicable index constraint is that, if any, defined for the
expression;
Static Semantics
Dynamic Semantics
The
evaluation of an
array_aggregate
of a given array type proceeds in two steps:
1.
Any
discrete_choices
of this aggregate and of its subaggregates are evaluated in an arbitrary
order, and converted to the corresponding index type;
2.
The array component expressions of the aggregate are evaluated in an
arbitrary order and their values are converted to the component subtype
of the array type; an array component expression is evaluated once for
each associated component.
Each
expression
in an
array_component_association
defines the value for the associated component(s). For an
array_component_association
with <>, the associated component(s) are initialized to the Default_Component_Value
of the array type if this aspect has been specified for the array type;
otherwise, they are initialized by default as for a stand-alone object
of the component subtype (see
3.3.1).
The
bounds of the index range of an
array_aggregate
(including a subaggregate) are determined as follows:
For an
array_aggregate
with an
others choice, the bounds are those of the corresponding
index range from the applicable index constraint;
For a
positional_array_aggregate
(or equivalent
string_literal)
without an
others choice, the lower bound is that of the corresponding
index range in the applicable index constraint, if defined, or that of
the corresponding index subtype, if not; in either case, the upper bound
is determined from the lower bound and the number of
expressions
(or the length of the
string_literal);
For an
array_aggregate,
a check is made that the index range defined by its bounds is compatible
with the corresponding index subtype.
For an
array_aggregate
with an
others choice, a check is made that no
expression
or <> is specified for an index value outside the bounds determined
by the applicable index constraint.
For a multidimensional
array_aggregate,
a check is made that all subaggregates that correspond to the same index
have the same bounds.
The exception Constraint_Error
is raised if any of the above checks fail.
Examples
Examples of array
aggregates with positional associations:
(7, 9, 5, 1, 3, 2, 4, 8, 6, 0)
Table'(5, 8, 4, 1,
others => 0) --
see 3.6
Examples of array
aggregates with named associations:
(1 .. 5 => (1 .. 8 => 0.0)) -- two-dimensional
(1 .. N => new Cell) -- N new cells, in particular for N = 0
Table'(2 | 4 | 10 => 1,
others => 0)
Schedule'(Mon .. Fri => True,
others => False) --
see 3.6
Schedule'(Wed | Sun => False,
others => True)
Vector'(1 => 2.5) --
single-component vector
Examples of two-dimensional
array aggregates:
--
Three aggregates for the same value of subtype Matrix(1..2,1..3) (see 3.6):
((1.1, 1.2, 1.3), (2.1, 2.2, 2.3))
(1 => (1.1, 1.2, 1.3), 2 => (2.1, 2.2, 2.3))
(1 => (1 => 1.1, 2 => 1.2, 3 => 1.3), 2 => (1 => 2.1, 2 => 2.2, 3 => 2.3))
Examples of aggregates
as initial values:
A : Table := (7, 9, 5, 1, 3, 2, 4, 8, 6, 0); -- A(1)=7, A(10)=0
B : Table := (2 | 4 | 10 => 1, others => 0); -- B(1)=0, B(10)=1
C : constant Matrix := (1 .. 5 => (1 .. 8 => 0.0)); -- C'Last(1)=5, C'Last(2)=8
D : Bit_Vector(M .. N) := (M .. N => True); --
see 3.6
E : Bit_Vector(M .. N) := (
others => True);
F : String(1 .. 1) := (1 => 'F'); --
a one component aggregate: same as "F"
Example of an array
aggregate with defaulted others choice and with an applicable index constraint
provided by an enclosing record aggregate:
Buffer'(Size => 50, Pos => 1, Value => String'('x',
others => <>)) --
see 3.7
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