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|
------------------------------------------------------------------------------
-- --
-- GNAT COMPILER COMPONENTS --
-- --
-- U I N T P --
-- --
-- B o d y --
-- --
-- Copyright (C) 1992-2007, Free Software Foundation, Inc. --
-- --
-- GNAT is free software; you can redistribute it and/or modify it under --
-- terms of the GNU General Public License as published by the Free Soft- --
-- ware Foundation; either version 2, or (at your option) any later ver- --
-- sion. GNAT is distributed in the hope that it will be useful, but WITH- --
-- OUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY --
-- or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License --
-- for more details. You should have received a copy of the GNU General --
-- Public License distributed with GNAT; see file COPYING. If not, write --
-- to the Free Software Foundation, 51 Franklin Street, Fifth Floor, --
-- Boston, MA 02110-1301, USA. --
-- --
-- As a special exception, if other files instantiate generics from this --
-- unit, or you link this unit with other files to produce an executable, --
-- this unit does not by itself cause the resulting executable to be --
-- covered by the GNU General Public License. This exception does not --
-- however invalidate any other reasons why the executable file might be --
-- covered by the GNU Public License. --
-- --
-- GNAT was originally developed by the GNAT team at New York University. --
-- Extensive contributions were provided by Ada Core Technologies Inc. --
-- --
------------------------------------------------------------------------------
with Output; use Output;
with Tree_IO; use Tree_IO;
with GNAT.HTable; use GNAT.HTable;
package body Uintp is
------------------------
-- Local Declarations --
------------------------
Uint_Int_First : Uint := Uint_0;
-- Uint value containing Int'First value, set by Initialize. The initial
-- value of Uint_0 is used for an assertion check that ensures that this
-- value is not used before it is initialized. This value is used in the
-- UI_Is_In_Int_Range predicate, and it is right that this is a host value,
-- since the issue is host representation of integer values.
Uint_Int_Last : Uint;
-- Uint value containing Int'Last value set by Initialize
UI_Power_2 : array (Int range 0 .. 64) of Uint;
-- This table is used to memoize exponentiations by powers of 2. The Nth
-- entry, if set, contains the Uint value 2 ** N. Initially UI_Power_2_Set
-- is zero and only the 0'th entry is set, the invariant being that all
-- entries in the range 0 .. UI_Power_2_Set are initialized.
UI_Power_2_Set : Nat;
-- Number of entries set in UI_Power_2;
UI_Power_10 : array (Int range 0 .. 64) of Uint;
-- This table is used to memoize exponentiations by powers of 10 in the
-- same manner as described above for UI_Power_2.
UI_Power_10_Set : Nat;
-- Number of entries set in UI_Power_10;
Uints_Min : Uint;
Udigits_Min : Int;
-- These values are used to make sure that the mark/release mechanism does
-- not destroy values saved in the U_Power tables or in the hash table used
-- by UI_From_Int. Whenever an entry is made in either of these tabls,
-- Uints_Min and Udigits_Min are updated to protect the entry, and Release
-- never cuts back beyond these minimum values.
Int_0 : constant Int := 0;
Int_1 : constant Int := 1;
Int_2 : constant Int := 2;
-- These values are used in some cases where the use of numeric literals
-- would cause ambiguities (integer vs Uint).
----------------------------
-- UI_From_Int Hash Table --
----------------------------
-- UI_From_Int uses a hash table to avoid duplicating entries and wasting
-- storage. This is particularly important for complex cases of back
-- annotation.
subtype Hnum is Nat range 0 .. 1022;
function Hash_Num (F : Int) return Hnum;
-- Hashing function
package UI_Ints is new Simple_HTable (
Header_Num => Hnum,
Element => Uint,
No_Element => No_Uint,
Key => Int,
Hash => Hash_Num,
Equal => "=");
-----------------------
-- Local Subprograms --
-----------------------
function Direct (U : Uint) return Boolean;
pragma Inline (Direct);
-- Returns True if U is represented directly
function Direct_Val (U : Uint) return Int;
-- U is a Uint for is represented directly. The returned result is the
-- value represented.
function GCD (Jin, Kin : Int) return Int;
-- Compute GCD of two integers. Assumes that Jin >= Kin >= 0
procedure Image_Out
(Input : Uint;
To_Buffer : Boolean;
Format : UI_Format);
-- Common processing for UI_Image and UI_Write, To_Buffer is set True for
-- UI_Image, and false for UI_Write, and Format is copied from the Format
-- parameter to UI_Image or UI_Write.
procedure Init_Operand (UI : Uint; Vec : out UI_Vector);
pragma Inline (Init_Operand);
-- This procedure puts the value of UI into the vector in canonical
-- multiple precision format. The parameter should be of the correct size
-- as determined by a previous call to N_Digits (UI). The first digit of
-- Vec contains the sign, all other digits are always non- negative. Note
-- that the input may be directly represented, and in this case Vec will
-- contain the corresponding one or two digit value. The low bound of Vec
-- is always 1.
function Least_Sig_Digit (Arg : Uint) return Int;
pragma Inline (Least_Sig_Digit);
-- Returns the Least Significant Digit of Arg quickly. When the given Uint
-- is less than 2**15, the value returned is the input value, in this case
-- the result may be negative. It is expected that any use will mask off
-- unnecessary bits. This is used for finding Arg mod B where B is a power
-- of two. Hence the actual base is irrelevent as long as it is a power of
-- two.
procedure Most_Sig_2_Digits
(Left : Uint;
Right : Uint;
Left_Hat : out Int;
Right_Hat : out Int);
-- Returns leading two significant digits from the given pair of Uint's.
-- Mathematically: returns Left / (Base ** K) and Right / (Base ** K) where
-- K is as small as possible S.T. Right_Hat < Base * Base. It is required
-- that Left > Right for the algorithm to work.
function N_Digits (Input : Uint) return Int;
pragma Inline (N_Digits);
-- Returns number of "digits" in a Uint
function Sum_Digits (Left : Uint; Sign : Int) return Int;
-- If Sign = 1 return the sum of the "digits" of Abs (Left). If the total
-- has more then one digit then return Sum_Digits of total.
function Sum_Double_Digits (Left : Uint; Sign : Int) return Int;
-- Same as above but work in New_Base = Base * Base
procedure UI_Div_Rem
(Left, Right : Uint;
Quotient : out Uint;
Remainder : out Uint;
Discard_Quotient : Boolean;
Discard_Remainder : Boolean);
-- Compute euclidian division of Left by Right, and return Quotient and
-- signed Remainder (Left rem Right).
--
-- If Discard_Quotient is True, Quotient is left unchanged.
-- If Discard_Remainder is True, Remainder is left unchanged.
function Vector_To_Uint
(In_Vec : UI_Vector;
Negative : Boolean) return Uint;
-- Functions that calculate values in UI_Vectors, call this function to
-- create and return the Uint value. In_Vec contains the multiple precision
-- (Base) representation of a non-negative value. Leading zeroes are
-- permitted. Negative is set if the desired result is the negative of the
-- given value. The result will be either the appropriate directly
-- represented value, or a table entry in the proper canonical format is
-- created and returned.
--
-- Note that Init_Operand puts a signed value in the result vector, but
-- Vector_To_Uint is always presented with a non-negative value. The
-- processing of signs is something that is done by the caller before
-- calling Vector_To_Uint.
------------
-- Direct --
------------
function Direct (U : Uint) return Boolean is
begin
return Int (U) <= Int (Uint_Direct_Last);
end Direct;
----------------
-- Direct_Val --
----------------
function Direct_Val (U : Uint) return Int is
begin
pragma Assert (Direct (U));
return Int (U) - Int (Uint_Direct_Bias);
end Direct_Val;
---------
-- GCD --
---------
function GCD (Jin, Kin : Int) return Int is
J, K, Tmp : Int;
begin
pragma Assert (Jin >= Kin);
pragma Assert (Kin >= Int_0);
J := Jin;
K := Kin;
while K /= Uint_0 loop
Tmp := J mod K;
J := K;
K := Tmp;
end loop;
return J;
end GCD;
--------------
-- Hash_Num --
--------------
function Hash_Num (F : Int) return Hnum is
begin
return Standard."mod" (F, Hnum'Range_Length);
end Hash_Num;
---------------
-- Image_Out --
---------------
procedure Image_Out
(Input : Uint;
To_Buffer : Boolean;
Format : UI_Format)
is
Marks : constant Uintp.Save_Mark := Uintp.Mark;
Base : Uint;
Ainput : Uint;
Digs_Output : Natural := 0;
-- Counts digits output. In hex mode, but not in decimal mode, we
-- put an underline after every four hex digits that are output.
Exponent : Natural := 0;
-- If the number is too long to fit in the buffer, we switch to an
-- approximate output format with an exponent. This variable records
-- the exponent value.
function Better_In_Hex return Boolean;
-- Determines if it is better to generate digits in base 16 (result
-- is true) or base 10 (result is false). The choice is purely a
-- matter of convenience and aesthetics, so it does not matter which
-- value is returned from a correctness point of view.
procedure Image_Char (C : Character);
-- Internal procedure to output one character
procedure Image_Exponent (N : Natural);
-- Output non-zero exponent. Note that we only use the exponent form in
-- the buffer case, so we know that To_Buffer is true.
procedure Image_Uint (U : Uint);
-- Internal procedure to output characters of non-negative Uint
-------------------
-- Better_In_Hex --
-------------------
function Better_In_Hex return Boolean is
T16 : constant Uint := Uint_2 ** Int'(16);
A : Uint;
begin
A := UI_Abs (Input);
-- Small values up to 2**16 can always be in decimal
if A < T16 then
return False;
end if;
-- Otherwise, see if we are a power of 2 or one less than a power
-- of 2. For the moment these are the only cases printed in hex.
if A mod Uint_2 = Uint_1 then
A := A + Uint_1;
end if;
loop
if A mod T16 /= Uint_0 then
return False;
else
A := A / T16;
end if;
exit when A < T16;
end loop;
while A > Uint_2 loop
if A mod Uint_2 /= Uint_0 then
return False;
else
A := A / Uint_2;
end if;
end loop;
return True;
end Better_In_Hex;
----------------
-- Image_Char --
----------------
procedure Image_Char (C : Character) is
begin
if To_Buffer then
if UI_Image_Length + 6 > UI_Image_Max then
Exponent := Exponent + 1;
else
UI_Image_Length := UI_Image_Length + 1;
UI_Image_Buffer (UI_Image_Length) := C;
end if;
else
Write_Char (C);
end if;
end Image_Char;
--------------------
-- Image_Exponent --
--------------------
procedure Image_Exponent (N : Natural) is
begin
if N >= 10 then
Image_Exponent (N / 10);
end if;
UI_Image_Length := UI_Image_Length + 1;
UI_Image_Buffer (UI_Image_Length) :=
Character'Val (Character'Pos ('0') + N mod 10);
end Image_Exponent;
----------------
-- Image_Uint --
----------------
procedure Image_Uint (U : Uint) is
H : constant array (Int range 0 .. 15) of Character :=
"0123456789ABCDEF";
begin
if U >= Base then
Image_Uint (U / Base);
end if;
if Digs_Output = 4 and then Base = Uint_16 then
Image_Char ('_');
Digs_Output := 0;
end if;
Image_Char (H (UI_To_Int (U rem Base)));
Digs_Output := Digs_Output + 1;
end Image_Uint;
-- Start of processing for Image_Out
begin
if Input = No_Uint then
Image_Char ('?');
return;
end if;
UI_Image_Length := 0;
if Input < Uint_0 then
Image_Char ('-');
Ainput := -Input;
else
Ainput := Input;
end if;
if Format = Hex
or else (Format = Auto and then Better_In_Hex)
then
Base := Uint_16;
Image_Char ('1');
Image_Char ('6');
Image_Char ('#');
Image_Uint (Ainput);
Image_Char ('#');
else
Base := Uint_10;
Image_Uint (Ainput);
end if;
if Exponent /= 0 then
UI_Image_Length := UI_Image_Length + 1;
UI_Image_Buffer (UI_Image_Length) := 'E';
Image_Exponent (Exponent);
end if;
Uintp.Release (Marks);
end Image_Out;
-------------------
-- Init_Operand --
-------------------
procedure Init_Operand (UI : Uint; Vec : out UI_Vector) is
Loc : Int;
pragma Assert (Vec'First = Int'(1));
begin
if Direct (UI) then
Vec (1) := Direct_Val (UI);
if Vec (1) >= Base then
Vec (2) := Vec (1) rem Base;
Vec (1) := Vec (1) / Base;
end if;
else
Loc := Uints.Table (UI).Loc;
for J in 1 .. Uints.Table (UI).Length loop
Vec (J) := Udigits.Table (Loc + J - 1);
end loop;
end if;
end Init_Operand;
----------------
-- Initialize --
----------------
procedure Initialize is
begin
Uints.Init;
Udigits.Init;
Uint_Int_First := UI_From_Int (Int'First);
Uint_Int_Last := UI_From_Int (Int'Last);
UI_Power_2 (0) := Uint_1;
UI_Power_2_Set := 0;
UI_Power_10 (0) := Uint_1;
UI_Power_10_Set := 0;
Uints_Min := Uints.Last;
Udigits_Min := Udigits.Last;
UI_Ints.Reset;
end Initialize;
---------------------
-- Least_Sig_Digit --
---------------------
function Least_Sig_Digit (Arg : Uint) return Int is
V : Int;
begin
if Direct (Arg) then
V := Direct_Val (Arg);
if V >= Base then
V := V mod Base;
end if;
-- Note that this result may be negative
return V;
else
return
Udigits.Table
(Uints.Table (Arg).Loc + Uints.Table (Arg).Length - 1);
end if;
end Least_Sig_Digit;
----------
-- Mark --
----------
function Mark return Save_Mark is
begin
return (Save_Uint => Uints.Last, Save_Udigit => Udigits.Last);
end Mark;
-----------------------
-- Most_Sig_2_Digits --
-----------------------
procedure Most_Sig_2_Digits
(Left : Uint;
Right : Uint;
Left_Hat : out Int;
Right_Hat : out Int)
is
begin
pragma Assert (Left >= Right);
if Direct (Left) then
Left_Hat := Direct_Val (Left);
Right_Hat := Direct_Val (Right);
return;
else
declare
L1 : constant Int :=
Udigits.Table (Uints.Table (Left).Loc);
L2 : constant Int :=
Udigits.Table (Uints.Table (Left).Loc + 1);
begin
-- It is not so clear what to return when Arg is negative???
Left_Hat := abs (L1) * Base + L2;
end;
end if;
declare
Length_L : constant Int := Uints.Table (Left).Length;
Length_R : Int;
R1 : Int;
R2 : Int;
T : Int;
begin
if Direct (Right) then
T := Direct_Val (Left);
R1 := abs (T / Base);
R2 := T rem Base;
Length_R := 2;
else
R1 := abs (Udigits.Table (Uints.Table (Right).Loc));
R2 := Udigits.Table (Uints.Table (Right).Loc + 1);
Length_R := Uints.Table (Right).Length;
end if;
if Length_L = Length_R then
Right_Hat := R1 * Base + R2;
elsif Length_L = Length_R + Int_1 then
Right_Hat := R1;
else
Right_Hat := 0;
end if;
end;
end Most_Sig_2_Digits;
---------------
-- N_Digits --
---------------
-- Note: N_Digits returns 1 for No_Uint
function N_Digits (Input : Uint) return Int is
begin
if Direct (Input) then
if Direct_Val (Input) >= Base then
return 2;
else
return 1;
end if;
else
return Uints.Table (Input).Length;
end if;
end N_Digits;
--------------
-- Num_Bits --
--------------
function Num_Bits (Input : Uint) return Nat is
Bits : Nat;
Num : Nat;
begin
-- Largest negative number has to be handled specially, since it is in
-- Int_Range, but we cannot take the absolute value.
if Input = Uint_Int_First then
return Int'Size;
-- For any other number in Int_Range, get absolute value of number
elsif UI_Is_In_Int_Range (Input) then
Num := abs (UI_To_Int (Input));
Bits := 0;
-- If not in Int_Range then initialize bit count for all low order
-- words, and set number to high order digit.
else
Bits := Base_Bits * (Uints.Table (Input).Length - 1);
Num := abs (Udigits.Table (Uints.Table (Input).Loc));
end if;
-- Increase bit count for remaining value in Num
while Types.">" (Num, 0) loop
Num := Num / 2;
Bits := Bits + 1;
end loop;
return Bits;
end Num_Bits;
---------
-- pid --
---------
procedure pid (Input : Uint) is
begin
UI_Write (Input, Decimal);
Write_Eol;
end pid;
---------
-- pih --
---------
procedure pih (Input : Uint) is
begin
UI_Write (Input, Hex);
Write_Eol;
end pih;
-------------
-- Release --
-------------
procedure Release (M : Save_Mark) is
begin
Uints.Set_Last (Uint'Max (M.Save_Uint, Uints_Min));
Udigits.Set_Last (Int'Max (M.Save_Udigit, Udigits_Min));
end Release;
----------------------
-- Release_And_Save --
----------------------
procedure Release_And_Save (M : Save_Mark; UI : in out Uint) is
begin
if Direct (UI) then
Release (M);
else
declare
UE_Len : constant Pos := Uints.Table (UI).Length;
UE_Loc : constant Int := Uints.Table (UI).Loc;
UD : constant Udigits.Table_Type (1 .. UE_Len) :=
Udigits.Table (UE_Loc .. UE_Loc + UE_Len - 1);
begin
Release (M);
Uints.Increment_Last;
UI := Uints.Last;
Uints.Table (UI) := (UE_Len, Udigits.Last + 1);
for J in 1 .. UE_Len loop
Udigits.Increment_Last;
Udigits.Table (Udigits.Last) := UD (J);
end loop;
end;
end if;
end Release_And_Save;
procedure Release_And_Save (M : Save_Mark; UI1, UI2 : in out Uint) is
begin
if Direct (UI1) then
Release_And_Save (M, UI2);
elsif Direct (UI2) then
Release_And_Save (M, UI1);
else
declare
UE1_Len : constant Pos := Uints.Table (UI1).Length;
UE1_Loc : constant Int := Uints.Table (UI1).Loc;
UD1 : constant Udigits.Table_Type (1 .. UE1_Len) :=
Udigits.Table (UE1_Loc .. UE1_Loc + UE1_Len - 1);
UE2_Len : constant Pos := Uints.Table (UI2).Length;
UE2_Loc : constant Int := Uints.Table (UI2).Loc;
UD2 : constant Udigits.Table_Type (1 .. UE2_Len) :=
Udigits.Table (UE2_Loc .. UE2_Loc + UE2_Len - 1);
begin
Release (M);
Uints.Increment_Last;
UI1 := Uints.Last;
Uints.Table (UI1) := (UE1_Len, Udigits.Last + 1);
for J in 1 .. UE1_Len loop
Udigits.Increment_Last;
Udigits.Table (Udigits.Last) := UD1 (J);
end loop;
Uints.Increment_Last;
UI2 := Uints.Last;
Uints.Table (UI2) := (UE2_Len, Udigits.Last + 1);
for J in 1 .. UE2_Len loop
Udigits.Increment_Last;
Udigits.Table (Udigits.Last) := UD2 (J);
end loop;
end;
end if;
end Release_And_Save;
----------------
-- Sum_Digits --
----------------
-- This is done in one pass
-- Mathematically: assume base congruent to 1 and compute an equivelent
-- integer to Left.
-- If Sign = -1 return the alternating sum of the "digits"
-- D1 - D2 + D3 - D4 + D5 ...
-- (where D1 is Least Significant Digit)
-- Mathematically: assume base congruent to -1 and compute an equivelent
-- integer to Left.
-- This is used in Rem and Base is assumed to be 2 ** 15
-- Note: The next two functions are very similar, any style changes made
-- to one should be reflected in both. These would be simpler if we
-- worked base 2 ** 32.
function Sum_Digits (Left : Uint; Sign : Int) return Int is
begin
pragma Assert (Sign = Int_1 or Sign = Int (-1));
-- First try simple case;
if Direct (Left) then
declare
Tmp_Int : Int := Direct_Val (Left);
begin
if Tmp_Int >= Base then
Tmp_Int := (Tmp_Int / Base) +
Sign * (Tmp_Int rem Base);
-- Now Tmp_Int is in [-(Base - 1) .. 2 * (Base - 1)]
if Tmp_Int >= Base then
-- Sign must be 1
Tmp_Int := (Tmp_Int / Base) + 1;
end if;
-- Now Tmp_Int is in [-(Base - 1) .. (Base - 1)]
end if;
return Tmp_Int;
end;
-- Otherwise full circuit is needed
else
declare
L_Length : constant Int := N_Digits (Left);
L_Vec : UI_Vector (1 .. L_Length);
Tmp_Int : Int;
Carry : Int;
Alt : Int;
begin
Init_Operand (Left, L_Vec);
L_Vec (1) := abs L_Vec (1);
Tmp_Int := 0;
Carry := 0;
Alt := 1;
for J in reverse 1 .. L_Length loop
Tmp_Int := Tmp_Int + Alt * (L_Vec (J) + Carry);
-- Tmp_Int is now between [-2 * Base + 1 .. 2 * Base - 1],
-- since old Tmp_Int is between [-(Base - 1) .. Base - 1]
-- and L_Vec is in [0 .. Base - 1] and Carry in [-1 .. 1]
if Tmp_Int >= Base then
Tmp_Int := Tmp_Int - Base;
Carry := 1;
elsif Tmp_Int <= -Base then
Tmp_Int := Tmp_Int + Base;
Carry := -1;
else
Carry := 0;
end if;
-- Tmp_Int is now between [-Base + 1 .. Base - 1]
Alt := Alt * Sign;
end loop;
Tmp_Int := Tmp_Int + Alt * Carry;
-- Tmp_Int is now between [-Base .. Base]
if Tmp_Int >= Base then
Tmp_Int := Tmp_Int - Base + Alt * Sign * 1;
elsif Tmp_Int <= -Base then
Tmp_Int := Tmp_Int + Base + Alt * Sign * (-1);
end if;
-- Now Tmp_Int is in [-(Base - 1) .. (Base - 1)]
return Tmp_Int;
end;
end if;
end Sum_Digits;
-----------------------
-- Sum_Double_Digits --
-----------------------
-- Note: This is used in Rem, Base is assumed to be 2 ** 15
function Sum_Double_Digits (Left : Uint; Sign : Int) return Int is
begin
-- First try simple case;
pragma Assert (Sign = Int_1 or Sign = Int (-1));
if Direct (Left) then
return Direct_Val (Left);
-- Otherwise full circuit is needed
else
declare
L_Length : constant Int := N_Digits (Left);
L_Vec : UI_Vector (1 .. L_Length);
Most_Sig_Int : Int;
Least_Sig_Int : Int;
Carry : Int;
J : Int;
Alt : Int;
begin
Init_Operand (Left, L_Vec);
L_Vec (1) := abs L_Vec (1);
Most_Sig_Int := 0;
Least_Sig_Int := 0;
Carry := 0;
Alt := 1;
J := L_Length;
while J > Int_1 loop
Least_Sig_Int := Least_Sig_Int + Alt * (L_Vec (J) + Carry);
-- Least is in [-2 Base + 1 .. 2 * Base - 1]
-- Since L_Vec in [0 .. Base - 1] and Carry in [-1 .. 1]
-- and old Least in [-Base + 1 .. Base - 1]
if Least_Sig_Int >= Base then
Least_Sig_Int := Least_Sig_Int - Base;
Carry := 1;
elsif Least_Sig_Int <= -Base then
Least_Sig_Int := Least_Sig_Int + Base;
Carry := -1;
else
Carry := 0;
end if;
-- Least is now in [-Base + 1 .. Base - 1]
Most_Sig_Int := Most_Sig_Int + Alt * (L_Vec (J - 1) + Carry);
-- Most is in [-2 Base + 1 .. 2 * Base - 1]
-- Since L_Vec in [0 .. Base - 1] and Carry in [-1 .. 1]
-- and old Most in [-Base + 1 .. Base - 1]
if Most_Sig_Int >= Base then
Most_Sig_Int := Most_Sig_Int - Base;
Carry := 1;
elsif Most_Sig_Int <= -Base then
Most_Sig_Int := Most_Sig_Int + Base;
Carry := -1;
else
Carry := 0;
end if;
-- Most is now in [-Base + 1 .. Base - 1]
J := J - 2;
Alt := Alt * Sign;
end loop;
if J = Int_1 then
Least_Sig_Int := Least_Sig_Int + Alt * (L_Vec (J) + Carry);
else
Least_Sig_Int := Least_Sig_Int + Alt * Carry;
end if;
if Least_Sig_Int >= Base then
Least_Sig_Int := Least_Sig_Int - Base;
Most_Sig_Int := Most_Sig_Int + Alt * 1;
elsif Least_Sig_Int <= -Base then
Least_Sig_Int := Least_Sig_Int + Base;
Most_Sig_Int := Most_Sig_Int + Alt * (-1);
end if;
if Most_Sig_Int >= Base then
Most_Sig_Int := Most_Sig_Int - Base;
Alt := Alt * Sign;
Least_Sig_Int :=
Least_Sig_Int + Alt * 1; -- cannot overflow again
elsif Most_Sig_Int <= -Base then
Most_Sig_Int := Most_Sig_Int + Base;
Alt := Alt * Sign;
Least_Sig_Int :=
Least_Sig_Int + Alt * (-1); -- cannot overflow again.
end if;
return Most_Sig_Int * Base + Least_Sig_Int;
end;
end if;
end Sum_Double_Digits;
---------------
-- Tree_Read --
---------------
procedure Tree_Read is
begin
Uints.Tree_Read;
Udigits.Tree_Read;
Tree_Read_Int (Int (Uint_Int_First));
Tree_Read_Int (Int (Uint_Int_Last));
Tree_Read_Int (UI_Power_2_Set);
Tree_Read_Int (UI_Power_10_Set);
Tree_Read_Int (Int (Uints_Min));
Tree_Read_Int (Udigits_Min);
for J in 0 .. UI_Power_2_Set loop
Tree_Read_Int (Int (UI_Power_2 (J)));
end loop;
for J in 0 .. UI_Power_10_Set loop
Tree_Read_Int (Int (UI_Power_10 (J)));
end loop;
end Tree_Read;
----------------
-- Tree_Write --
----------------
procedure Tree_Write is
begin
Uints.Tree_Write;
Udigits.Tree_Write;
Tree_Write_Int (Int (Uint_Int_First));
Tree_Write_Int (Int (Uint_Int_Last));
Tree_Write_Int (UI_Power_2_Set);
Tree_Write_Int (UI_Power_10_Set);
Tree_Write_Int (Int (Uints_Min));
Tree_Write_Int (Udigits_Min);
for J in 0 .. UI_Power_2_Set loop
Tree_Write_Int (Int (UI_Power_2 (J)));
end loop;
for J in 0 .. UI_Power_10_Set loop
Tree_Write_Int (Int (UI_Power_10 (J)));
end loop;
end Tree_Write;
-------------
-- UI_Abs --
-------------
function UI_Abs (Right : Uint) return Uint is
begin
if Right < Uint_0 then
return -Right;
else
return Right;
end if;
end UI_Abs;
-------------
-- UI_Add --
-------------
function UI_Add (Left : Int; Right : Uint) return Uint is
begin
return UI_Add (UI_From_Int (Left), Right);
end UI_Add;
function UI_Add (Left : Uint; Right : Int) return Uint is
begin
return UI_Add (Left, UI_From_Int (Right));
end UI_Add;
function UI_Add (Left : Uint; Right : Uint) return Uint is
begin
-- Simple cases of direct operands and addition of zero
if Direct (Left) then
if Direct (Right) then
return UI_From_Int (Direct_Val (Left) + Direct_Val (Right));
elsif Int (Left) = Int (Uint_0) then
return Right;
end if;
elsif Direct (Right) and then Int (Right) = Int (Uint_0) then
return Left;
end if;
-- Otherwise full circuit is needed
declare
L_Length : constant Int := N_Digits (Left);
R_Length : constant Int := N_Digits (Right);
L_Vec : UI_Vector (1 .. L_Length);
R_Vec : UI_Vector (1 .. R_Length);
Sum_Length : Int;
Tmp_Int : Int;
Carry : Int;
Borrow : Int;
X_Bigger : Boolean := False;
Y_Bigger : Boolean := False;
Result_Neg : Boolean := False;
begin
Init_Operand (Left, L_Vec);
Init_Operand (Right, R_Vec);
-- At least one of the two operands is in multi-digit form.
-- Calculate the number of digits sufficient to hold result.
if L_Length > R_Length then
Sum_Length := L_Length + 1;
X_Bigger := True;
else
Sum_Length := R_Length + 1;
if R_Length > L_Length then
Y_Bigger := True;
end if;
end if;
-- Make copies of the absolute values of L_Vec and R_Vec into X and Y
-- both with lengths equal to the maximum possibly needed. This makes
-- looping over the digits much simpler.
declare
X : UI_Vector (1 .. Sum_Length);
Y : UI_Vector (1 .. Sum_Length);
Tmp_UI : UI_Vector (1 .. Sum_Length);
begin
for J in 1 .. Sum_Length - L_Length loop
X (J) := 0;
end loop;
X (Sum_Length - L_Length + 1) := abs L_Vec (1);
for J in 2 .. L_Length loop
X (J + (Sum_Length - L_Length)) := L_Vec (J);
end loop;
for J in 1 .. Sum_Length - R_Length loop
Y (J) := 0;
end loop;
Y (Sum_Length - R_Length + 1) := abs R_Vec (1);
for J in 2 .. R_Length loop
Y (J + (Sum_Length - R_Length)) := R_Vec (J);
end loop;
if (L_Vec (1) < Int_0) = (R_Vec (1) < Int_0) then
-- Same sign so just add
Carry := 0;
for J in reverse 1 .. Sum_Length loop
Tmp_Int := X (J) + Y (J) + Carry;
if Tmp_Int >= Base then
Tmp_Int := Tmp_Int - Base;
Carry := 1;
else
Carry := 0;
end if;
X (J) := Tmp_Int;
end loop;
return Vector_To_Uint (X, L_Vec (1) < Int_0);
else
-- Find which one has bigger magnitude
if not (X_Bigger or Y_Bigger) then
for J in L_Vec'Range loop
if abs L_Vec (J) > abs R_Vec (J) then
X_Bigger := True;
exit;
elsif abs R_Vec (J) > abs L_Vec (J) then
Y_Bigger := True;
exit;
end if;
end loop;
end if;
-- If they have identical magnitude, just return 0, else swap
-- if necessary so that X had the bigger magnitude. Determine
-- if result is negative at this time.
Result_Neg := False;
if not (X_Bigger or Y_Bigger) then
return Uint_0;
elsif Y_Bigger then
if R_Vec (1) < Int_0 then
Result_Neg := True;
end if;
Tmp_UI := X;
X := Y;
Y := Tmp_UI;
else
if L_Vec (1) < Int_0 then
Result_Neg := True;
end if;
end if;
-- Subtract Y from the bigger X
Borrow := 0;
for J in reverse 1 .. Sum_Length loop
Tmp_Int := X (J) - Y (J) + Borrow;
if Tmp_Int < Int_0 then
Tmp_Int := Tmp_Int + Base;
Borrow := -1;
else
Borrow := 0;
end if;
X (J) := Tmp_Int;
end loop;
return Vector_To_Uint (X, Result_Neg);
end if;
end;
end;
end UI_Add;
--------------------------
-- UI_Decimal_Digits_Hi --
--------------------------
function UI_Decimal_Digits_Hi (U : Uint) return Nat is
begin
-- The maximum value of a "digit" is 32767, which is 5 decimal digits,
-- so an N_Digit number could take up to 5 times this number of digits.
-- This is certainly too high for large numbers but it is not worth
-- worrying about.
return 5 * N_Digits (U);
end UI_Decimal_Digits_Hi;
--------------------------
-- UI_Decimal_Digits_Lo --
--------------------------
function UI_Decimal_Digits_Lo (U : Uint) return Nat is
begin
-- The maximum value of a "digit" is 32767, which is more than four
-- decimal digits, but not a full five digits. The easily computed
-- minimum number of decimal digits is thus 1 + 4 * the number of
-- digits. This is certainly too low for large numbers but it is not
-- worth worrying about.
return 1 + 4 * (N_Digits (U) - 1);
end UI_Decimal_Digits_Lo;
------------
-- UI_Div --
------------
function UI_Div (Left : Int; Right : Uint) return Uint is
begin
return UI_Div (UI_From_Int (Left), Right);
end UI_Div;
function UI_Div (Left : Uint; Right : Int) return Uint is
begin
return UI_Div (Left, UI_From_Int (Right));
end UI_Div;
function UI_Div (Left, Right : Uint) return Uint is
Quotient : Uint;
Remainder : Uint;
begin
UI_Div_Rem
(Left, Right,
Quotient, Remainder,
Discard_Quotient => False,
Discard_Remainder => True);
return Quotient;
end UI_Div;
----------------
-- UI_Div_Rem --
----------------
procedure UI_Div_Rem
(Left, Right : Uint;
Quotient : out Uint;
Remainder : out Uint;
Discard_Quotient : Boolean;
Discard_Remainder : Boolean)
is
begin
pragma Assert (Right /= Uint_0);
-- Cases where both operands are represented directly
if Direct (Left) and then Direct (Right) then
declare
DV_Left : constant Int := Direct_Val (Left);
DV_Right : constant Int := Direct_Val (Right);
begin
if not Discard_Quotient then
Quotient := UI_From_Int (DV_Left / DV_Right);
end if;
if not Discard_Remainder then
Remainder := UI_From_Int (DV_Left rem DV_Right);
end if;
return;
end;
end if;
declare
L_Length : constant Int := N_Digits (Left);
R_Length : constant Int := N_Digits (Right);
Q_Length : constant Int := L_Length - R_Length + 1;
L_Vec : UI_Vector (1 .. L_Length);
R_Vec : UI_Vector (1 .. R_Length);
D : Int;
Remainder_I : Int;
Tmp_Divisor : Int;
Carry : Int;
Tmp_Int : Int;
Tmp_Dig : Int;
procedure UI_Div_Vector
(L_Vec : UI_Vector;
R_Int : Int;
Quotient : out UI_Vector;
Remainder : out Int);
pragma Inline (UI_Div_Vector);
-- Specialised variant for case where the divisor is a single digit
procedure UI_Div_Vector
(L_Vec : UI_Vector;
R_Int : Int;
Quotient : out UI_Vector;
Remainder : out Int)
is
Tmp_Int : Int;
begin
Remainder := 0;
for J in L_Vec'Range loop
Tmp_Int := Remainder * Base + abs L_Vec (J);
Quotient (Quotient'First + J - L_Vec'First) := Tmp_Int / R_Int;
Remainder := Tmp_Int rem R_Int;
end loop;
if L_Vec (L_Vec'First) < Int_0 then
Remainder := -Remainder;
end if;
end UI_Div_Vector;
-- Start of processing for UI_Div_Rem
begin
-- Result is zero if left operand is shorter than right
if L_Length < R_Length then
if not Discard_Quotient then
Quotient := Uint_0;
end if;
if not Discard_Remainder then
Remainder := Left;
end if;
return;
end if;
Init_Operand (Left, L_Vec);
Init_Operand (Right, R_Vec);
-- Case of right operand is single digit. Here we can simply divide
-- each digit of the left operand by the divisor, from most to least
-- significant, carrying the remainder to the next digit (just like
-- ordinary long division by hand).
if R_Length = Int_1 then
Tmp_Divisor := abs R_Vec (1);
declare
Quotient_V : UI_Vector (1 .. L_Length);
begin
UI_Div_Vector (L_Vec, Tmp_Divisor, Quotient_V, Remainder_I);
if not Discard_Quotient then
Quotient :=
Vector_To_Uint
(Quotient_V, (L_Vec (1) < Int_0 xor R_Vec (1) < Int_0));
end if;
if not Discard_Remainder then
Remainder := UI_From_Int (Remainder_I);
end if;
return;
end;
end if;
-- The possible simple cases have been exhausted. Now turn to the
-- algorithm D from the section of Knuth mentioned at the top of
-- this package.
Algorithm_D : declare
Dividend : UI_Vector (1 .. L_Length + 1);
Divisor : UI_Vector (1 .. R_Length);
Quotient_V : UI_Vector (1 .. Q_Length);
Divisor_Dig1 : Int;
Divisor_Dig2 : Int;
Q_Guess : Int;
begin
-- [ NORMALIZE ] (step D1 in the algorithm). First calculate the
-- scale d, and then multiply Left and Right (u and v in the book)
-- by d to get the dividend and divisor to work with.
D := Base / (abs R_Vec (1) + 1);
Dividend (1) := 0;
Dividend (2) := abs L_Vec (1);
for J in 3 .. L_Length + Int_1 loop
Dividend (J) := L_Vec (J - 1);
end loop;
Divisor (1) := abs R_Vec (1);
for J in Int_2 .. R_Length loop
Divisor (J) := R_Vec (J);
end loop;
if D > Int_1 then
-- Multiply Dividend by D
Carry := 0;
for J in reverse Dividend'Range loop
Tmp_Int := Dividend (J) * D + Carry;
Dividend (J) := Tmp_Int rem Base;
Carry := Tmp_Int / Base;
end loop;
-- Multiply Divisor by d
Carry := 0;
for J in reverse Divisor'Range loop
Tmp_Int := Divisor (J) * D + Carry;
Divisor (J) := Tmp_Int rem Base;
Carry := Tmp_Int / Base;
end loop;
end if;
-- Main loop of long division algorithm
Divisor_Dig1 := Divisor (1);
Divisor_Dig2 := Divisor (2);
for J in Quotient_V'Range loop
-- [ CALCULATE Q (hat) ] (step D3 in the algorithm)
Tmp_Int := Dividend (J) * Base + Dividend (J + 1);
-- Initial guess
if Dividend (J) = Divisor_Dig1 then
Q_Guess := Base - 1;
else
Q_Guess := Tmp_Int / Divisor_Dig1;
end if;
-- Refine the guess
while Divisor_Dig2 * Q_Guess >
(Tmp_Int - Q_Guess * Divisor_Dig1) * Base +
Dividend (J + 2)
loop
Q_Guess := Q_Guess - 1;
end loop;
-- [ MULTIPLY & SUBTRACT ] (step D4). Q_Guess * Divisor is
-- subtracted from the remaining dividend.
Carry := 0;
for K in reverse Divisor'Range loop
Tmp_Int := Dividend (J + K) - Q_Guess * Divisor (K) + Carry;
Tmp_Dig := Tmp_Int rem Base;
Carry := Tmp_Int / Base;
if Tmp_Dig < Int_0 then
Tmp_Dig := Tmp_Dig + Base;
Carry := Carry - 1;
end if;
Dividend (J + K) := Tmp_Dig;
end loop;
Dividend (J) := Dividend (J) + Carry;
-- [ TEST REMAINDER ] & [ ADD BACK ] (steps D5 and D6)
-- Here there is a slight difference from the book: the last
-- carry is always added in above and below (cancelling each
-- other). In fact the dividend going negative is used as
-- the test.
-- If the Dividend went negative, then Q_Guess was off by
-- one, so it is decremented, and the divisor is added back
-- into the relevant portion of the dividend.
if Dividend (J) < Int_0 then
Q_Guess := Q_Guess - 1;
Carry := 0;
for K in reverse Divisor'Range loop
Tmp_Int := Dividend (J + K) + Divisor (K) + Carry;
if Tmp_Int >= Base then
Tmp_Int := Tmp_Int - Base;
Carry := 1;
else
Carry := 0;
end if;
Dividend (J + K) := Tmp_Int;
end loop;
Dividend (J) := Dividend (J) + Carry;
end if;
-- Finally we can get the next quotient digit
Quotient_V (J) := Q_Guess;
end loop;
-- [ UNNORMALIZE ] (step D8)
if not Discard_Quotient then
Quotient := Vector_To_Uint
(Quotient_V, (L_Vec (1) < Int_0 xor R_Vec (1) < Int_0));
end if;
if not Discard_Remainder then
declare
Remainder_V : UI_Vector (1 .. R_Length);
Discard_Int : Int;
begin
UI_Div_Vector
(Dividend (Dividend'Last - R_Length + 1 .. Dividend'Last),
D,
Remainder_V, Discard_Int);
Remainder := Vector_To_Uint (Remainder_V, L_Vec (1) < Int_0);
end;
end if;
end Algorithm_D;
end;
end UI_Div_Rem;
------------
-- UI_Eq --
------------
function UI_Eq (Left : Int; Right : Uint) return Boolean is
begin
return not UI_Ne (UI_From_Int (Left), Right);
end UI_Eq;
function UI_Eq (Left : Uint; Right : Int) return Boolean is
begin
return not UI_Ne (Left, UI_From_Int (Right));
end UI_Eq;
function UI_Eq (Left : Uint; Right : Uint) return Boolean is
begin
return not UI_Ne (Left, Right);
end UI_Eq;
--------------
-- UI_Expon --
--------------
function UI_Expon (Left : Int; Right : Uint) return Uint is
begin
return UI_Expon (UI_From_Int (Left), Right);
end UI_Expon;
function UI_Expon (Left : Uint; Right : Int) return Uint is
begin
return UI_Expon (Left, UI_From_Int (Right));
end UI_Expon;
function UI_Expon (Left : Int; Right : Int) return Uint is
begin
return UI_Expon (UI_From_Int (Left), UI_From_Int (Right));
end UI_Expon;
function UI_Expon (Left : Uint; Right : Uint) return Uint is
begin
pragma Assert (Right >= Uint_0);
-- Any value raised to power of 0 is 1
if Right = Uint_0 then
return Uint_1;
-- 0 to any positive power is 0
elsif Left = Uint_0 then
return Uint_0;
-- 1 to any power is 1
elsif Left = Uint_1 then
return Uint_1;
-- Any value raised to power of 1 is that value
elsif Right = Uint_1 then
return Left;
-- Cases which can be done by table lookup
elsif Right <= Uint_64 then
-- 2 ** N for N in 2 .. 64
if Left = Uint_2 then
declare
Right_Int : constant Int := Direct_Val (Right);
begin
if Right_Int > UI_Power_2_Set then
for J in UI_Power_2_Set + Int_1 .. Right_Int loop
UI_Power_2 (J) := UI_Power_2 (J - Int_1) * Int_2;
Uints_Min := Uints.Last;
Udigits_Min := Udigits.Last;
end loop;
UI_Power_2_Set := Right_Int;
end if;
return UI_Power_2 (Right_Int);
end;
-- 10 ** N for N in 2 .. 64
elsif Left = Uint_10 then
declare
Right_Int : constant Int := Direct_Val (Right);
begin
if Right_Int > UI_Power_10_Set then
for J in UI_Power_10_Set + Int_1 .. Right_Int loop
UI_Power_10 (J) := UI_Power_10 (J - Int_1) * Int (10);
Uints_Min := Uints.Last;
Udigits_Min := Udigits.Last;
end loop;
UI_Power_10_Set := Right_Int;
end if;
return UI_Power_10 (Right_Int);
end;
end if;
end if;
-- If we fall through, then we have the general case (see Knuth 4.6.3)
declare
N : Uint := Right;
Squares : Uint := Left;
Result : Uint := Uint_1;
M : constant Uintp.Save_Mark := Uintp.Mark;
begin
loop
if (Least_Sig_Digit (N) mod Int_2) = Int_1 then
Result := Result * Squares;
end if;
N := N / Uint_2;
exit when N = Uint_0;
Squares := Squares * Squares;
end loop;
Uintp.Release_And_Save (M, Result);
return Result;
end;
end UI_Expon;
----------------
-- UI_From_CC --
----------------
function UI_From_CC (Input : Char_Code) return Uint is
begin
return UI_From_Dint (Dint (Input));
end UI_From_CC;
------------------
-- UI_From_Dint --
------------------
function UI_From_Dint (Input : Dint) return Uint is
begin
if Dint (Min_Direct) <= Input and then Input <= Dint (Max_Direct) then
return Uint (Dint (Uint_Direct_Bias) + Input);
-- For values of larger magnitude, compute digits into a vector and call
-- Vector_To_Uint.
else
declare
Max_For_Dint : constant := 5;
-- Base is defined so that 5 Uint digits is sufficient to hold the
-- largest possible Dint value.
V : UI_Vector (1 .. Max_For_Dint);
Temp_Integer : Dint;
begin
for J in V'Range loop
V (J) := 0;
end loop;
Temp_Integer := Input;
for J in reverse V'Range loop
V (J) := Int (abs (Temp_Integer rem Dint (Base)));
Temp_Integer := Temp_Integer / Dint (Base);
end loop;
return Vector_To_Uint (V, Input < Dint'(0));
end;
end if;
end UI_From_Dint;
-----------------
-- UI_From_Int --
-----------------
function UI_From_Int (Input : Int) return Uint is
U : Uint;
begin
if Min_Direct <= Input and then Input <= Max_Direct then
return Uint (Int (Uint_Direct_Bias) + Input);
end if;
-- If already in the hash table, return entry
U := UI_Ints.Get (Input);
if U /= No_Uint then
return U;
end if;
-- For values of larger magnitude, compute digits into a vector and call
-- Vector_To_Uint.
declare
Max_For_Int : constant := 3;
-- Base is defined so that 3 Uint digits is sufficient to hold the
-- largest possible Int value.
V : UI_Vector (1 .. Max_For_Int);
Temp_Integer : Int;
begin
for J in V'Range loop
V (J) := 0;
end loop;
Temp_Integer := Input;
for J in reverse V'Range loop
V (J) := abs (Temp_Integer rem Base);
Temp_Integer := Temp_Integer / Base;
end loop;
U := Vector_To_Uint (V, Input < Int_0);
UI_Ints.Set (Input, U);
Uints_Min := Uints.Last;
Udigits_Min := Udigits.Last;
return U;
end;
end UI_From_Int;
------------
-- UI_GCD --
------------
-- Lehmer's algorithm for GCD
-- The idea is to avoid using multiple precision arithmetic wherever
-- possible, substituting Int arithmetic instead. See Knuth volume II,
-- Algorithm L (page 329).
-- We use the same notation as Knuth (U_Hat standing for the obvious!)
function UI_GCD (Uin, Vin : Uint) return Uint is
U, V : Uint;
-- Copies of Uin and Vin
U_Hat, V_Hat : Int;
-- The most Significant digits of U,V
A, B, C, D, T, Q, Den1, Den2 : Int;
Tmp_UI : Uint;
Marks : constant Uintp.Save_Mark := Uintp.Mark;
Iterations : Integer := 0;
begin
pragma Assert (Uin >= Vin);
pragma Assert (Vin >= Uint_0);
U := Uin;
V := Vin;
loop
Iterations := Iterations + 1;
if Direct (V) then
if V = Uint_0 then
return U;
else
return
UI_From_Int (GCD (Direct_Val (V), UI_To_Int (U rem V)));
end if;
end if;
Most_Sig_2_Digits (U, V, U_Hat, V_Hat);
A := 1;
B := 0;
C := 0;
D := 1;
loop
-- We might overflow and get division by zero here. This just
-- means we cannot take the single precision step
Den1 := V_Hat + C;
Den2 := V_Hat + D;
exit when (Den1 * Den2) = Int_0;
-- Compute Q, the trial quotient
Q := (U_Hat + A) / Den1;
exit when Q /= ((U_Hat + B) / Den2);
-- A single precision step Euclid step will give same answer as a
-- multiprecision one.
T := A - (Q * C);
A := C;
C := T;
T := B - (Q * D);
B := D;
D := T;
T := U_Hat - (Q * V_Hat);
U_Hat := V_Hat;
V_Hat := T;
end loop;
-- Take a multiprecision Euclid step
if B = Int_0 then
-- No single precision steps take a regular Euclid step
Tmp_UI := U rem V;
U := V;
V := Tmp_UI;
else
-- Use prior single precision steps to compute this Euclid step
-- For constructs such as:
-- sqrt_2: constant := 1.41421_35623_73095_04880_16887_24209_698;
-- sqrt_eps: constant long_float := long_float( 1.0 / sqrt_2)
-- ** long_float'machine_mantissa;
--
-- we spend 80% of our time working on this step. Perhaps we need
-- a special case Int / Uint dot product to speed things up. ???
-- Alternatively we could increase the single precision iterations
-- to handle Uint's of some small size ( <5 digits?). Then we
-- would have more iterations on small Uint. On the code above, we
-- only get 5 (on average) single precision iterations per large
-- iteration. ???
Tmp_UI := (UI_From_Int (A) * U) + (UI_From_Int (B) * V);
V := (UI_From_Int (C) * U) + (UI_From_Int (D) * V);
U := Tmp_UI;
end if;
-- If the operands are very different in magnitude, the loop will
-- generate large amounts of short-lived data, which it is worth
-- removing periodically.
if Iterations > 100 then
Release_And_Save (Marks, U, V);
Iterations := 0;
end if;
end loop;
end UI_GCD;
------------
-- UI_Ge --
------------
function UI_Ge (Left : Int; Right : Uint) return Boolean is
begin
return not UI_Lt (UI_From_Int (Left), Right);
end UI_Ge;
function UI_Ge (Left : Uint; Right : Int) return Boolean is
begin
return not UI_Lt (Left, UI_From_Int (Right));
end UI_Ge;
function UI_Ge (Left : Uint; Right : Uint) return Boolean is
begin
return not UI_Lt (Left, Right);
end UI_Ge;
------------
-- UI_Gt --
------------
function UI_Gt (Left : Int; Right : Uint) return Boolean is
begin
return UI_Lt (Right, UI_From_Int (Left));
end UI_Gt;
function UI_Gt (Left : Uint; Right : Int) return Boolean is
begin
return UI_Lt (UI_From_Int (Right), Left);
end UI_Gt;
function UI_Gt (Left : Uint; Right : Uint) return Boolean is
begin
return UI_Lt (Right, Left);
end UI_Gt;
---------------
-- UI_Image --
---------------
procedure UI_Image (Input : Uint; Format : UI_Format := Auto) is
begin
Image_Out (Input, True, Format);
end UI_Image;
-------------------------
-- UI_Is_In_Int_Range --
-------------------------
function UI_Is_In_Int_Range (Input : Uint) return Boolean is
begin
-- Make sure we don't get called before Initialize
pragma Assert (Uint_Int_First /= Uint_0);
if Direct (Input) then
return True;
else
return Input >= Uint_Int_First
and then Input <= Uint_Int_Last;
end if;
end UI_Is_In_Int_Range;
------------
-- UI_Le --
------------
function UI_Le (Left : Int; Right : Uint) return Boolean is
begin
return not UI_Lt (Right, UI_From_Int (Left));
end UI_Le;
function UI_Le (Left : Uint; Right : Int) return Boolean is
begin
return not UI_Lt (UI_From_Int (Right), Left);
end UI_Le;
function UI_Le (Left : Uint; Right : Uint) return Boolean is
begin
return not UI_Lt (Right, Left);
end UI_Le;
------------
-- UI_Lt --
------------
function UI_Lt (Left : Int; Right : Uint) return Boolean is
begin
return UI_Lt (UI_From_Int (Left), Right);
end UI_Lt;
function UI_Lt (Left : Uint; Right : Int) return Boolean is
begin
return UI_Lt (Left, UI_From_Int (Right));
end UI_Lt;
function UI_Lt (Left : Uint; Right : Uint) return Boolean is
begin
-- Quick processing for identical arguments
if Int (Left) = Int (Right) then
return False;
-- Quick processing for both arguments directly represented
elsif Direct (Left) and then Direct (Right) then
return Int (Left) < Int (Right);
-- At least one argument is more than one digit long
else
declare
L_Length : constant Int := N_Digits (Left);
R_Length : constant Int := N_Digits (Right);
L_Vec : UI_Vector (1 .. L_Length);
R_Vec : UI_Vector (1 .. R_Length);
begin
Init_Operand (Left, L_Vec);
Init_Operand (Right, R_Vec);
if L_Vec (1) < Int_0 then
-- First argument negative, second argument non-negative
if R_Vec (1) >= Int_0 then
return True;
-- Both arguments negative
else
if L_Length /= R_Length then
return L_Length > R_Length;
elsif L_Vec (1) /= R_Vec (1) then
return L_Vec (1) < R_Vec (1);
else
for J in 2 .. L_Vec'Last loop
if L_Vec (J) /= R_Vec (J) then
return L_Vec (J) > R_Vec (J);
end if;
end loop;
return False;
end if;
end if;
else
-- First argument non-negative, second argument negative
if R_Vec (1) < Int_0 then
return False;
-- Both arguments non-negative
else
if L_Length /= R_Length then
return L_Length < R_Length;
else
for J in L_Vec'Range loop
if L_Vec (J) /= R_Vec (J) then
return L_Vec (J) < R_Vec (J);
end if;
end loop;
return False;
end if;
end if;
end if;
end;
end if;
end UI_Lt;
------------
-- UI_Max --
------------
function UI_Max (Left : Int; Right : Uint) return Uint is
begin
return UI_Max (UI_From_Int (Left), Right);
end UI_Max;
function UI_Max (Left : Uint; Right : Int) return Uint is
begin
return UI_Max (Left, UI_From_Int (Right));
end UI_Max;
function UI_Max (Left : Uint; Right : Uint) return Uint is
begin
if Left >= Right then
return Left;
else
return Right;
end if;
end UI_Max;
------------
-- UI_Min --
------------
function UI_Min (Left : Int; Right : Uint) return Uint is
begin
return UI_Min (UI_From_Int (Left), Right);
end UI_Min;
function UI_Min (Left : Uint; Right : Int) return Uint is
begin
return UI_Min (Left, UI_From_Int (Right));
end UI_Min;
function UI_Min (Left : Uint; Right : Uint) return Uint is
begin
if Left <= Right then
return Left;
else
return Right;
end if;
end UI_Min;
-------------
-- UI_Mod --
-------------
function UI_Mod (Left : Int; Right : Uint) return Uint is
begin
return UI_Mod (UI_From_Int (Left), Right);
end UI_Mod;
function UI_Mod (Left : Uint; Right : Int) return Uint is
begin
return UI_Mod (Left, UI_From_Int (Right));
end UI_Mod;
function UI_Mod (Left : Uint; Right : Uint) return Uint is
Urem : constant Uint := Left rem Right;
begin
if (Left < Uint_0) = (Right < Uint_0)
or else Urem = Uint_0
then
return Urem;
else
return Right + Urem;
end if;
end UI_Mod;
-------------------------------
-- UI_Modular_Exponentiation --
-------------------------------
function UI_Modular_Exponentiation
(B : Uint;
E : Uint;
Modulo : Uint) return Uint
is
M : constant Save_Mark := Mark;
Result : Uint := Uint_1;
Base : Uint := B;
Exponent : Uint := E;
begin
while Exponent /= Uint_0 loop
if Least_Sig_Digit (Exponent) rem Int'(2) = Int'(1) then
Result := (Result * Base) rem Modulo;
end if;
Exponent := Exponent / Uint_2;
Base := (Base * Base) rem Modulo;
end loop;
Release_And_Save (M, Result);
return Result;
end UI_Modular_Exponentiation;
------------------------
-- UI_Modular_Inverse --
------------------------
function UI_Modular_Inverse (N : Uint; Modulo : Uint) return Uint is
M : constant Save_Mark := Mark;
U : Uint;
V : Uint;
Q : Uint;
R : Uint;
X : Uint;
Y : Uint;
T : Uint;
S : Int := 1;
begin
U := Modulo;
V := N;
X := Uint_1;
Y := Uint_0;
loop
UI_Div_Rem
(U, V,
Quotient => Q, Remainder => R,
Discard_Quotient => False,
Discard_Remainder => False);
U := V;
V := R;
T := X;
X := Y + Q * X;
Y := T;
S := -S;
exit when R = Uint_1;
end loop;
if S = Int'(-1) then
X := Modulo - X;
end if;
Release_And_Save (M, X);
return X;
end UI_Modular_Inverse;
------------
-- UI_Mul --
------------
function UI_Mul (Left : Int; Right : Uint) return Uint is
begin
return UI_Mul (UI_From_Int (Left), Right);
end UI_Mul;
function UI_Mul (Left : Uint; Right : Int) return Uint is
begin
return UI_Mul (Left, UI_From_Int (Right));
end UI_Mul;
function UI_Mul (Left : Uint; Right : Uint) return Uint is
begin
-- Simple case of single length operands
if Direct (Left) and then Direct (Right) then
return
UI_From_Dint
(Dint (Direct_Val (Left)) * Dint (Direct_Val (Right)));
end if;
-- Otherwise we have the general case (Algorithm M in Knuth)
declare
L_Length : constant Int := N_Digits (Left);
R_Length : constant Int := N_Digits (Right);
L_Vec : UI_Vector (1 .. L_Length);
R_Vec : UI_Vector (1 .. R_Length);
Neg : Boolean;
begin
Init_Operand (Left, L_Vec);
Init_Operand (Right, R_Vec);
Neg := (L_Vec (1) < Int_0) xor (R_Vec (1) < Int_0);
L_Vec (1) := abs (L_Vec (1));
R_Vec (1) := abs (R_Vec (1));
Algorithm_M : declare
Product : UI_Vector (1 .. L_Length + R_Length);
Tmp_Sum : Int;
Carry : Int;
begin
for J in Product'Range loop
Product (J) := 0;
end loop;
for J in reverse R_Vec'Range loop
Carry := 0;
for K in reverse L_Vec'Range loop
Tmp_Sum :=
L_Vec (K) * R_Vec (J) + Product (J + K) + Carry;
Product (J + K) := Tmp_Sum rem Base;
Carry := Tmp_Sum / Base;
end loop;
Product (J) := Carry;
end loop;
return Vector_To_Uint (Product, Neg);
end Algorithm_M;
end;
end UI_Mul;
------------
-- UI_Ne --
------------
function UI_Ne (Left : Int; Right : Uint) return Boolean is
begin
return UI_Ne (UI_From_Int (Left), Right);
end UI_Ne;
function UI_Ne (Left : Uint; Right : Int) return Boolean is
begin
return UI_Ne (Left, UI_From_Int (Right));
end UI_Ne;
function UI_Ne (Left : Uint; Right : Uint) return Boolean is
begin
-- Quick processing for identical arguments. Note that this takes
-- care of the case of two No_Uint arguments.
if Int (Left) = Int (Right) then
return False;
end if;
-- See if left operand directly represented
if Direct (Left) then
-- If right operand directly represented then compare
if Direct (Right) then
return Int (Left) /= Int (Right);
-- Left operand directly represented, right not, must be unequal
else
return True;
end if;
-- Right operand directly represented, left not, must be unequal
elsif Direct (Right) then
return True;
end if;
-- Otherwise both multi-word, do comparison
declare
Size : constant Int := N_Digits (Left);
Left_Loc : Int;
Right_Loc : Int;
begin
if Size /= N_Digits (Right) then
return True;
end if;
Left_Loc := Uints.Table (Left).Loc;
Right_Loc := Uints.Table (Right).Loc;
for J in Int_0 .. Size - Int_1 loop
if Udigits.Table (Left_Loc + J) /=
Udigits.Table (Right_Loc + J)
then
return True;
end if;
end loop;
return False;
end;
end UI_Ne;
----------------
-- UI_Negate --
----------------
function UI_Negate (Right : Uint) return Uint is
begin
-- Case where input is directly represented. Note that since the range
-- of Direct values is non-symmetrical, the result may not be directly
-- represented, this is taken care of in UI_From_Int.
if Direct (Right) then
return UI_From_Int (-Direct_Val (Right));
-- Full processing for multi-digit case. Note that we cannot just copy
-- the value to the end of the table negating the first digit, since the
-- range of Direct values is non-symmetrical, so we can have a negative
-- value that is not Direct whose negation can be represented directly.
else
declare
R_Length : constant Int := N_Digits (Right);
R_Vec : UI_Vector (1 .. R_Length);
Neg : Boolean;
begin
Init_Operand (Right, R_Vec);
Neg := R_Vec (1) > Int_0;
R_Vec (1) := abs R_Vec (1);
return Vector_To_Uint (R_Vec, Neg);
end;
end if;
end UI_Negate;
-------------
-- UI_Rem --
-------------
function UI_Rem (Left : Int; Right : Uint) return Uint is
begin
return UI_Rem (UI_From_Int (Left), Right);
end UI_Rem;
function UI_Rem (Left : Uint; Right : Int) return Uint is
begin
return UI_Rem (Left, UI_From_Int (Right));
end UI_Rem;
function UI_Rem (Left, Right : Uint) return Uint is
Sign : Int;
Tmp : Int;
subtype Int1_12 is Integer range 1 .. 12;
begin
pragma Assert (Right /= Uint_0);
if Direct (Right) then
if Direct (Left) then
return UI_From_Int (Direct_Val (Left) rem Direct_Val (Right));
else
-- Special cases when Right is less than 13 and Left is larger
-- larger than one digit. All of these algorithms depend on the
-- base being 2 ** 15 We work with Abs (Left) and Abs(Right)
-- then multiply result by Sign (Left)
if (Right <= Uint_12) and then (Right >= Uint_Minus_12) then
if Left < Uint_0 then
Sign := -1;
else
Sign := 1;
end if;
-- All cases are listed, grouped by mathematical method It is
-- not inefficient to do have this case list out of order since
-- GCC sorts the cases we list.
case Int1_12 (abs (Direct_Val (Right))) is
when 1 =>
return Uint_0;
-- Powers of two are simple AND's with LS Left Digit GCC
-- will recognise these constants as powers of 2 and replace
-- the rem with simpler operations where possible.
-- Least_Sig_Digit might return Negative numbers
when 2 =>
return UI_From_Int (
Sign * (Least_Sig_Digit (Left) mod 2));
when 4 =>
return UI_From_Int (
Sign * (Least_Sig_Digit (Left) mod 4));
when 8 =>
return UI_From_Int (
Sign * (Least_Sig_Digit (Left) mod 8));
-- Some number theoretical tricks:
-- If B Rem Right = 1 then
-- Left Rem Right = Sum_Of_Digits_Base_B (Left) Rem Right
-- Note: 2^32 mod 3 = 1
when 3 =>
return UI_From_Int (
Sign * (Sum_Double_Digits (Left, 1) rem Int (3)));
-- Note: 2^15 mod 7 = 1
when 7 =>
return UI_From_Int (
Sign * (Sum_Digits (Left, 1) rem Int (7)));
-- Note: 2^32 mod 5 = -1
-- Alternating sums might be negative, but rem is always
-- positive hence we must use mod here.
when 5 =>
Tmp := Sum_Double_Digits (Left, -1) mod Int (5);
return UI_From_Int (Sign * Tmp);
-- Note: 2^15 mod 9 = -1
-- Alternating sums might be negative, but rem is always
-- positive hence we must use mod here.
when 9 =>
Tmp := Sum_Digits (Left, -1) mod Int (9);
return UI_From_Int (Sign * Tmp);
-- Note: 2^15 mod 11 = -1
-- Alternating sums might be negative, but rem is always
-- positive hence we must use mod here.
when 11 =>
Tmp := Sum_Digits (Left, -1) mod Int (11);
return UI_From_Int (Sign * Tmp);
-- Now resort to Chinese Remainder theorem to reduce 6, 10,
-- 12 to previous special cases
-- There is no reason we could not add more cases like these
-- if it proves useful.
-- Perhaps we should go up to 16, however we have no "trick"
-- for 13.
-- To find u mod m we:
-- Pick m1, m2 S.T.
-- GCD(m1, m2) = 1 AND m = (m1 * m2).
-- Next we pick (Basis) M1, M2 small S.T.
-- (M1 mod m1) = (M2 mod m2) = 1 AND
-- (M1 mod m2) = (M2 mod m1) = 0
-- So u mod m = (u1 * M1 + u2 * M2) mod m Where u1 = (u mod
-- m1) AND u2 = (u mod m2); Under typical circumstances the
-- last mod m can be done with a (possible) single
-- subtraction.
-- m1 = 2; m2 = 3; M1 = 3; M2 = 4;
when 6 =>
Tmp := 3 * (Least_Sig_Digit (Left) rem 2) +
4 * (Sum_Double_Digits (Left, 1) rem 3);
return UI_From_Int (Sign * (Tmp rem 6));
-- m1 = 2; m2 = 5; M1 = 5; M2 = 6;
when 10 =>
Tmp := 5 * (Least_Sig_Digit (Left) rem 2) +
6 * (Sum_Double_Digits (Left, -1) mod 5);
return UI_From_Int (Sign * (Tmp rem 10));
-- m1 = 3; m2 = 4; M1 = 4; M2 = 9;
when 12 =>
Tmp := 4 * (Sum_Double_Digits (Left, 1) rem 3) +
9 * (Least_Sig_Digit (Left) rem 4);
return UI_From_Int (Sign * (Tmp rem 12));
end case;
end if;
-- Else fall through to general case
-- The special case Length (Left) = Length (Right) = 1 in Div
-- looks slow. It uses UI_To_Int when Int should suffice. ???
end if;
end if;
declare
Quotient, Remainder : Uint;
begin
UI_Div_Rem
(Left, Right, Quotient, Remainder,
Discard_Quotient => True,
Discard_Remainder => False);
return Remainder;
end;
end UI_Rem;
------------
-- UI_Sub --
------------
function UI_Sub (Left : Int; Right : Uint) return Uint is
begin
return UI_Add (Left, -Right);
end UI_Sub;
function UI_Sub (Left : Uint; Right : Int) return Uint is
begin
return UI_Add (Left, -Right);
end UI_Sub;
function UI_Sub (Left : Uint; Right : Uint) return Uint is
begin
if Direct (Left) and then Direct (Right) then
return UI_From_Int (Direct_Val (Left) - Direct_Val (Right));
else
return UI_Add (Left, -Right);
end if;
end UI_Sub;
--------------
-- UI_To_CC --
--------------
function UI_To_CC (Input : Uint) return Char_Code is
begin
if Direct (Input) then
return Char_Code (Direct_Val (Input));
-- Case of input is more than one digit
else
declare
In_Length : constant Int := N_Digits (Input);
In_Vec : UI_Vector (1 .. In_Length);
Ret_CC : Char_Code;
begin
Init_Operand (Input, In_Vec);
-- We assume value is positive
Ret_CC := 0;
for Idx in In_Vec'Range loop
Ret_CC := Ret_CC * Char_Code (Base) +
Char_Code (abs In_Vec (Idx));
end loop;
return Ret_CC;
end;
end if;
end UI_To_CC;
----------------
-- UI_To_Int --
----------------
function UI_To_Int (Input : Uint) return Int is
begin
if Direct (Input) then
return Direct_Val (Input);
-- Case of input is more than one digit
else
declare
In_Length : constant Int := N_Digits (Input);
In_Vec : UI_Vector (1 .. In_Length);
Ret_Int : Int;
begin
-- Uints of more than one digit could be outside the range for
-- Ints. Caller should have checked for this if not certain.
-- Fatal error to attempt to convert from value outside Int'Range.
pragma Assert (UI_Is_In_Int_Range (Input));
-- Otherwise, proceed ahead, we are OK
Init_Operand (Input, In_Vec);
Ret_Int := 0;
-- Calculate -|Input| and then negates if value is positive. This
-- handles our current definition of Int (based on 2s complement).
-- Is it secure enough???
for Idx in In_Vec'Range loop
Ret_Int := Ret_Int * Base - abs In_Vec (Idx);
end loop;
if In_Vec (1) < Int_0 then
return Ret_Int;
else
return -Ret_Int;
end if;
end;
end if;
end UI_To_Int;
--------------
-- UI_Write --
--------------
procedure UI_Write (Input : Uint; Format : UI_Format := Auto) is
begin
Image_Out (Input, False, Format);
end UI_Write;
---------------------
-- Vector_To_Uint --
---------------------
function Vector_To_Uint
(In_Vec : UI_Vector;
Negative : Boolean)
return Uint
is
Size : Int;
Val : Int;
begin
-- The vector can contain leading zeros. These are not stored in the
-- table, so loop through the vector looking for first non-zero digit
for J in In_Vec'Range loop
if In_Vec (J) /= Int_0 then
-- The length of the value is the length of the rest of the vector
Size := In_Vec'Last - J + 1;
-- One digit value can always be represented directly
if Size = Int_1 then
if Negative then
return Uint (Int (Uint_Direct_Bias) - In_Vec (J));
else
return Uint (Int (Uint_Direct_Bias) + In_Vec (J));
end if;
-- Positive two digit values may be in direct representation range
elsif Size = Int_2 and then not Negative then
Val := In_Vec (J) * Base + In_Vec (J + 1);
if Val <= Max_Direct then
return Uint (Int (Uint_Direct_Bias) + Val);
end if;
end if;
-- The value is outside the direct representation range and must
-- therefore be stored in the table. Expand the table to contain
-- the count and tigis. The index of the new table entry will be
-- returned as the result.
Uints.Increment_Last;
Uints.Table (Uints.Last).Length := Size;
Uints.Table (Uints.Last).Loc := Udigits.Last + 1;
Udigits.Increment_Last;
if Negative then
Udigits.Table (Udigits.Last) := -In_Vec (J);
else
Udigits.Table (Udigits.Last) := +In_Vec (J);
end if;
for K in 2 .. Size loop
Udigits.Increment_Last;
Udigits.Table (Udigits.Last) := In_Vec (J + K - 1);
end loop;
return Uints.Last;
end if;
end loop;
-- Dropped through loop only if vector contained all zeros
return Uint_0;
end Vector_To_Uint;
end Uintp;
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