AdventOfCode2023/UPolynomialRoots.pas

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{
Solutions to the Advent Of Code.
Copyright (C) 2024 Stefan Müller
This program is free software: you can redistribute it and/or modify it under
the terms of the GNU General Public License as published by the Free Software
Foundation, either version 3 of the License, or (at your option) any later
version.
This program is distributed in the hope that it will be useful, but WITHOUT
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 along with
this program. If not, see <http://www.gnu.org/licenses/>.
}
unit UPolynomialRoots;
{$mode ObjFPC}{$H+}
interface
uses
Classes, SysUtils, Generics.Collections, UPolynomial, UBigInt;
type
{ TIsolatingInterval }
// Represents an isolating interval of the form [C / 2^K, (C + H) / 2^K] in respect to [0, 1] or [A, B] in respect to
// [0, bound], with A = C * bound / 2^K and B = (C + H) * bound / 2^K.
TIsolatingInterval = record
C, K, H: Cardinal;
Bound, A, B: TBigInt;
end;
TIsolatingIntervals = specialize TList<TIsolatingInterval>;
{ TRootIsolation }
TRootIsolation = class
private
function CalcSimpleRootBound(constref APolynomial: TBigIntPolynomial): TBigInt;
function GetIsolatingInterval(const AC, AK, AH: Cardinal; constref ABound: TBigInt): TIsolatingInterval;
public
function Bisect(constref APolynomial: TBigIntPolynomial): TIsolatingIntervals;
function Bisect(constref APolynomial: TBigIntPolynomial; constref ABound: TBigInt): TIsolatingIntervals;
end;
implementation
{ TRootIsolation }
function TRootIsolation.CalcSimpleRootBound(constref APolynomial: TBigIntPolynomial): TBigInt;
var
i, sign: Integer;
an, ai, max: TBigInt;
numeratorBit, denominatorBit: Int64;
begin
// We need a_n > 0 here, so we use -sign(a_n) instead of actually flipping the polynomial.
// Sign is not 0 because a_n is not 0.
an := APolynomial.Coefficient[APolynomial.Degree];
sign := -an.Sign;
// This is a simplification of Cauchy's bound to avoid division and make it a power of two.
// https://en.wikipedia.org/wiki/Geometrical_properties_of_polynomial_roots#Bounds_of_positive_real_roots
max := TBigInt.Zero;
for i := 0 to APolynomial.Degree - 1 do begin
ai := sign * APolynomial.Coefficient[i];
if max < ai then
max := ai;
end;
numeratorBit := max.GetMostSignificantBitIndex + 1;
denominatorBit := an.GetMostSignificantBitIndex;
Result := TBigInt.One << (numeratorBit - denominatorBit);
end;
function TRootIsolation.GetIsolatingInterval(const AC, AK, AH: Cardinal; constref ABound: TBigInt): TIsolatingInterval;
begin
Result.C := AC;
Result.K := AK;
Result.H := AH;
Result.Bound := ABound;
Result.A := (AC * ABound) >> AK;
Result.B := ((AC + AH) * ABound) >> AK;
end;
function TRootIsolation.Bisect(constref APolynomial: TBigIntPolynomial): TIsolatingIntervals;
var
bound: TBigInt;
begin
bound := CalcSimpleRootBound(APolynomial);
Result := Bisect(APolynomial, bound);
end;
// This is adapted from
// https://en.wikipedia.org/wiki/Real-root_isolation#Bisection_method
function TRootIsolation.Bisect(constref APolynomial: TBigIntPolynomial; constref ABound: TBigInt): TIsolatingIntervals;
type
TWorkItem = record
C, K: Cardinal;
P: TBigIntPolynomial;
end;
TWorkStack = specialize TStack<TWorkItem>;
var
item: TWorkItem;
stack: TWorkStack;
n, v: Integer;
varq: TBigIntPolynomial;
begin
Result := TIsolatingIntervals.Create;
stack := TWorkStack.Create;
item.C := 0;
item.K := 0;
item.P := APolynomial.ScaleVariable(ABound);
stack.Push(item);
n := item.P.Degree;
while stack.Count > 0 do
begin
item := stack.Pop;
if item.P.Coefficient[0] = TBigInt.Zero then
begin
// Found an integer root at 0.
item.P := item.P.DivideByVariable;
Dec(n);
Result.Add(GetIsolatingInterval(item.C, item.K, 0, ABound));
end;
varq := item.P.RevertOrderOfCoefficients.TranslateVariableByOne;
v := varq.CalcSignVariations;
if v = 1 then
begin
// Found isolating interval.
Result.Add(GetIsolatingInterval(item.C, item.K, 1, ABound));
end
else if v > 1 then
begin
// Bisects, first new work item is (2c, k + 1, 2^n * q(x/2)).
item.C := item.C << 1;
Inc(item.K);
item.P := item.P.ScaleVariableByHalf.ScaleByPowerOfTwo(n);
stack.Push(item);
// ... second new work item is (2c + 1, k + 1, 2^n * q((x+1)/2)).
item.C := item.C + 1;
item.P := item.P.TranslateVariableByOne;
stack.Push(item);
end;
end;
stack.Free;
end;
end.