[Ada] Compiler abort on use of Invalid_Value on numeric positive subtype
Invalid_Value in most cases uses a predefined numeric value from a
built-in table, but if the type does not include zero in its range, the
literal 0 is used instead. In that case the value (produced by a call to
Get_Simple_Init_Val) must be resolved for proper type information.
The following must compile quietly:
gnatmake -q main
----
with Problems; use Problems;
with Text_IO; use Text_IO;
procedure Main is
begin
Put_Line ("P1: " & P1'Image);
Put_Line ("P2: " & P2'Image);
Put_Line ("P3: " & P3'Image);
Put_Line ("P4: " & P4'Image);
end Main;
--
package Problems is
function P1 return Integer;
function P2 return Long_Integer;
-- Max. number of prime factors a number can have is log_2 N
-- For N =
600851475143, this is ~ 40
-- type P3_Factors is array (1 .. 40) of Long_Integer;
function P3 return Long_Integer;
type P4_Palindrome is range 100*100 .. 999*999;
function P4 return P4_Palindrome;
end Problems;
----
package body Problems is
function P1 return Integer is separate;
function P2 return Long_Integer is separate;
function P3 return Long_Integer is separate;
function P4 return P4_Palindrome is separate;
end Problems;
----
separate(Problems)
function P1 return Integer is
Sum : Integer range 0 .. 500_500 := 0;
begin
for I in Integer range 1 .. 1000 - 1 loop
if I mod 3 = 0 or I mod 5 = 0 then
Sum := Sum + I;
end if;
end loop;
return Sum;
end P1;
--
separate(Problems)
function P2 return Long_Integer is
subtype Total is Long_Integer range 0 .. 8_000002e6 ;
subtype Elem is Total range 0 .. 4e7 ;
Sum : Total := 0;
a, b, c : Elem;
begin
a := 1;
b := 2;
loop
if b mod 2 = 0 then
Sum := Sum + b;
end if;
c := b;
b := a + b;
a := c;
exit when b >= 4e6;
end loop;
return Sum;
end P2;
--
with Text_IO; use Text_IO;
with Ada.Numerics.Elementary_Functions; use Ada.Numerics.Elementary_Functions;
separate(Problems)
function P3 return Long_Integer is
-- Greatest prime factor
GPF : Long_Integer := 1;
Dividend : Long_Integer :=
600851475143;
Factor : Long_Integer := 2;
Quotient : Long_Integer;
begin
while Dividend > 1 loop
Quotient := Dividend / Factor;
if Dividend mod Factor = 0 then
GPF := Factor;
Dividend := Quotient;
else
if Factor >= Quotient then
GPF := Dividend;
exit;
end if;
Factor := Factor + 1;
end if;
end loop;
return GPF;
end P3;
----
with Text_IO; use Text_IO;
separate(Problems)
function P4 return P4_Palindrome is
type TripleDigit is range 100 .. 999;
a, b: TripleDigit := TripleDigit'First;
c : P4_Palindrome;
Max_Palindrome : P4_Palindrome := P4_Palindrome'Invalid_Value;
function Is_Palindrome (X : in P4_Palindrome) return Boolean is
type Int_Digit is range 0 .. 9;
type Int_Digits is array (1 .. 6) of Int_Digit;
type Digit_Extractor is range 0 .. P4_Palindrome'Last;
Y : Digit_Extractor := Digit_Extractor (X);
X_Digits : Int_Digits;
begin
for I in reverse X_Digits'Range loop
X_Digits (I) := Int_Digit (Y mod 10);
Y := Y / 10;
end loop;
return
(X_Digits (1) = X_Digits (6) and X_Digits (2) = X_Digits (5) and
X_Digits (3) = X_Digits (4)) or
(X_Digits (2) = X_Digits (6) and X_Digits (3) = X_Digits (5) and
X_Digits(1) = 0);
end Is_Palindrome;
begin
for a in TripleDigit'Range loop
for b in TripleDigit'Range loop
c := P4_Palindrome (a * b);
if Is_Palindrome (c) then
if Max_Palindrome'Valid or else c > Max_Palindrome then
Max_Palindrome := c;
end if;
end if;
end loop;
end loop;
return Max_Palindrome;
end;
2019-07-01 Ed Schonberg <schonberg@adacore.com>
gcc/ada/
* exp_attr.adb (Expand_Attribute_Reference, case Invalid_Value):
Resolve result of call to Get_Simple_Init_Val, which may be a
conversion of a literal.
git-svn-id: svn+ssh://gcc.gnu.org/svn/gcc/trunk@272855
138bc75d-0d04-0410-961f-
82ee72b054a4
projects / thirdparty / gcc.git / commit
