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4.5.5 Multiplying Operators
Static Semantics
1
The
multiplying operators * (multiplication), / (division),
mod (modulus),
and
rem (remainder) are predefined for every specific integer
type
T:
2
function "*" (Left, Right : T) return T
function "/" (Left, Right : T) return T
function "mod"(Left, Right : T) return T
function "rem"(Left, Right : T) return T
3
Signed integer multiplication has its conventional
meaning.
4
Signed integer division
and remainder are defined by the relation:
5
A = (A/B)*B + (A rem B)
6
where (A rem
B) has the sign of A and an absolute value less than the absolute value
of B. Signed integer division satisfies the identity:
7
(-A)/B = -(A/B) = A/(-B)
8
The signed integer
modulus operator is defined such that the result of A mod B has
the sign of B and an absolute value less than the absolute value of B;
in addition, for some signed integer value N, this result satisfies the
relation:
9
A = B*N + (A mod B)
10
The multiplying operators on modular types are
defined in terms of the corresponding signed integer operators, followed
by a reduction modulo the modulus if the result is outside the base range
of the type (which is only possible for the "*" operator).
11
Multiplication
and division operators are predefined for every specific floating point
type T:
12
function "*"(Left, Right : T) return T
function "/"(Left, Right : T) return T
13
The following multiplication
and division operators, with an operand of the predefined type Integer,
are predefined for every specific fixed point type T:
14
function "*"(Left : T; Right : Integer) return T
function "*"(Left : Integer; Right : T) return T
function "/"(Left : T; Right : Integer) return T
15
All of the above
multiplying operators are usable with an operand of an appropriate universal
numeric type. The following additional multiplying operators for root_real
are predefined, and are usable when both operands are of an appropriate
universal or root numeric type, and the result is allowed to be of type
root_real, as in a number_declaration:
16
function "*"(Left, Right : root_real) return root_real
function "/"(Left, Right : root_real) return root_real
17
function "*"(Left : root_real; Right : root_integer) return root_real
function "*"(Left : root_integer; Right : root_real) return root_real
function "/"(Left : root_real; Right : root_integer) return root_real
18
Multiplication
and division between any two fixed point types are provided by the following
two predefined operators:
19
function "*"(Left, Right : universal_fixed) return universal_fixed
function "/"(Left, Right : universal_fixed) return universal_fixed
Legality Rules
20
The above two fixed-fixed multiplying operators
shall not be used in a context where the expected type for the result
is itself universal_fixed -- the context has to identify some
other numeric type to which the result is to be converted, either explicitly
or implicitly.
Dynamic Semantics
21
The multiplication and division operators for
real types have their conventional meaning. For floating point types,
the accuracy of the result is determined by the precision of the result
type. For decimal fixed point types, the result is truncated toward zero
if the mathematical result is between two multiples of the
small
of the specific result type (possibly determined by context); for ordinary
fixed point types, if the mathematical result is between two multiples
of the
small, it is unspecified which of the two is the result.
22
The
exception Constraint_Error is raised by integer division,
rem,
and
mod if the right operand is zero. Similarly, for a real type
T with
T'Machine_Overflows True, division by zero raises
Constraint_Error.
23
17 For
positive A and B, A/B is the quotient and A rem B is the remainder
when A is divided by B. The following relations are satisfied by the
rem operator:
24
A rem (-B) = A rem B
(-A) rem B = -(A rem B)
25
18 For
any signed integer K, the following identity holds:
26
A mod B = (A + K*B) mod B
27
The
relations between signed integer division, remainder, and modulus are
illustrated by the following table:
28
A B A/B A rem B A mod B A B A/B A rem B A mod B
29
10 5 2 0 0 -10 5 -2 0 0
11 5 2 1 1 -11 5 -2 -1 4
12 5 2 2 2 -12 5 -2 -2 3
13 5 2 3 3 -13 5 -2 -3 2
14 5 2 4 4 -14 5 -2 -4 1
30
A B A/B A rem B A mod B A B A/B A rem B A mod B
10 -5 -2 0 0 -10 -5 2 0 0
11 -5 -2 1 -4 -11 -5 2 -1 -1
12 -5 -2 2 -3 -12 -5 2 -2 -2
13 -5 -2 3 -2 -13 -5 2 -3 -3
14 -5 -2 4 -1 -14 -5 2 -4 -4
Examples
31
Examples of
expressions involving multiplying operators:
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I : Integer := 1;
J : Integer := 2;
K : Integer := 3;
33
X : Real := 1.0; -- see 3.5.7
Y : Real := 2.0;
34
F : Fraction := 0.25; -- see 3.5.9
G : Fraction := 0.5;
35
Expression Value Result Type
I*J 2 same as I and J, that is, Integer
K/J 1 same as K and J, that is, Integer
K mod J 1 same as K and J, that is, Integer
X/Y 0.5 same as X and Y, that is, Real
F/2 0.125 same as F, that is, Fraction
3*F 0.75 same as F, that is, Fraction
0.75*G 0.375 universal_fixed, implicitly convertible
to any fixed point type
Fraction(F*G) 0.125 Fraction, as stated by the conversion
Real(J)*Y 4.0 Real, the type of both operands after
conversion of J
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