Gegeben N modulare Gleichungen: A ? X1mod(m1) . . A ? XNmod(mN) Finden Sie x in der Gleichung A ? xmod(m1*M2*M3..*MN) wo michist eine Primzahl oder eine Potenz einer Primzahl und i nimmt Werte von 1 bis n an. Die Eingabe erfolgt in Form von zwei Arrays, wobei das erste ein Array ist, das die Werte jedes x enthältichund das zweite Array enthält die Wertemenge jeder Primzahl. MichGeben Sie eine Ganzzahl für den Wert von x in der endgültigen Gleichung aus.
Beispiele:
Consider the two equations A ? 2mod(3) A ? 3mod(5) Input : 2 3 3 5 Output : 8 Consider the four equations A ? 3mod(4) A ? 4mod(7) A ? 1mod(9) (32) A ? 0mod(11) Input : 3 4 1 0 4 7 9 11 Output : 1243
Erläuterung : Unser Ziel ist es, diese Gleichungen jeweils zu zweit zu lösen. Wir nehmen die ersten beiden Gleichungen, kombinieren sie und verwenden dieses Ergebnis zur Kombination mit der dritten Gleichung und so weiter. Der Vorgang der Kombination zweier Gleichungen wird anhand von Beispiel 2 wie folgt erläutert:
- A ? 3mod(4) und A ? 4mod(7) sind die beiden Gleichungen, die uns zunächst zur Verfügung gestellt werden. Die resultierende Gleichung sei ein A? Xmod(m1* M2).
- Aist gegeben durch m1' * M1* X+ m' * M* X1wo m1' = modulare Umkehrung von m1Modul mund m' = modulare Umkehrung von mModul m1
- Wir können die modulare Umkehrung mithilfe des erweiterten euklidischen Algorithmus berechnen.
- Wir finden xA seinmod (m1* M2)
- Wir bekommen unsere neue Gleichung zu A? 11mod(28) wobei A 95 ist
- Wir versuchen nun, dies mit Gleichung 3 zu kombinieren und erhalten auf ähnliche Weise A ? 235mod(252) wobei A = 2503
- Und wenn wir dies schließlich mit Gleichung 4 kombinieren, erhalten wir A? 1243mod(2772) wobei A = 59455 und x = 1243
Wir stellen fest, dass 2772 zu Recht 4 * 7 * 9 * 11 entspricht. Wir haben somit den Wert von x für die endgültige Gleichung gefunden. Sie können darauf verweisen Erweiterter euklidischer Algorithmus Und Modulare multiplikative Umkehrung Weitere Informationen zu diesen Themen finden Sie hier.
C++// C++ program to combine modular equations // using Chinese Remainder Theorem #include // we then remove the first two elements // from the list of remainders and replace // it with the remainder value which will // be temp1 % temp2 x.erase(x.begin()); x.erase(x.begin()); x.insert(x.begin() temp1%temp2); //we then remove the first two values from //the list of modulii as we no longer require // them and simply replace them with the new // modulii that we calculated m.erase(m.begin()); m.erase(m.begin()); m.insert(m.begin() temp2); // once the list has only one element left // we can break as it will only contain // the value of our final remainder if(x.size()== 1){ break; } } // returns the remainder of the final equation return x[0]; } // driver segment int main(){ vector<int> m = {4 7 9 11}; vector<int> x = {3 4 1 0}; cout << crt(m x) << endl; return 0; } // The code is contributed by Gautam goel (gautamgoe962)
// Java program to implement the Chinese Remainder Theorem import java.util.ArrayList; import java.math.BigInteger; public class ChineseRemainderTheorem { // Function to calculate the modular inverse of a and m public static BigInteger modinv(BigInteger a BigInteger m) { BigInteger m0 = m; BigInteger y = BigInteger.ZERO; BigInteger x = BigInteger.ONE; if (m.equals(BigInteger.ONE)) return BigInteger.ZERO; while (a.compareTo(BigInteger.ONE) == 1) { BigInteger q = a.divide(m); BigInteger t = m; m = a.mod(m); a = t; t = y; y = x.subtract(q.multiply(y)); x = t; } if (x.compareTo(BigInteger.ZERO) == -1) x = x.add(m0); return x; } // Function to implement the Chinese Remainder Theorem public static BigInteger crt(ArrayList<BigInteger> m ArrayList<BigInteger> x) { BigInteger M = BigInteger.ONE; for (int i = 0; i < m.size(); i++) { M = M.multiply(m.get(i)); } BigInteger result = BigInteger.ZERO; for (int i = 0; i < m.size(); i++) { BigInteger Mi = M.divide(m.get(i)); BigInteger MiInv = modinv(Mi m.get(i)); result = result.add(x.get(i).multiply(Mi).multiply(MiInv)); } return result.mod(M); } public static void main(String[] args) { ArrayList<BigInteger> m = new ArrayList<>(); ArrayList<BigInteger> x = new ArrayList<>(); m.add(BigInteger.valueOf(4)); m.add(BigInteger.valueOf(7)); m.add(BigInteger.valueOf(9)); m.add(BigInteger.valueOf(11)); x.add(BigInteger.valueOf(3)); x.add(BigInteger.valueOf(4)); x.add(BigInteger.valueOf(1)); x.add(BigInteger.valueOf(0)); System.out.println(crt(m x)); } } // This code is contributed by Vikram_Shirsat
# Python 2.x program to combine modular equations # using Chinese Remainder Theorem # function that implements Extended euclidean # algorithm def extended_euclidean(a b): if a == 0: return (b 0 1) else: g y x = extended_euclidean(b % a a) return (g x - (b // a) * y y) # modular inverse driver function def modinv(a m): g x y = extended_euclidean(a m) return x % m # function implementing Chinese remainder theorem # list m contains all the modulii # list x contains the remainders of the equations def crt(m x): # We run this loop while the list of # remainders has length greater than 1 while True: # temp1 will contain the new value # of A. which is calculated according # to the equation m1' * m1 * x0 + m0' # * m0 * x1 temp1 = modinv(m[1]m[0]) * x[0] * m[1] + modinv(m[0]m[1]) * x[1] * m[0] # temp2 contains the value of the modulus # in the new equation which will be the # product of the modulii of the two # equations that we are combining temp2 = m[0] * m[1] # we then remove the first two elements # from the list of remainders and replace # it with the remainder value which will # be temp1 % temp2 x.remove(x[0]) x.remove(x[0]) x = [temp1 % temp2] + x # we then remove the first two values from # the list of modulii as we no longer require # them and simply replace them with the new # modulii that we calculated m.remove(m[0]) m.remove(m[0]) m = [temp2] + m # once the list has only one element left # we can break as it will only contain # the value of our final remainder if len(x) == 1: break # returns the remainder of the final equation return x[0] # driver segment m = [4 7 9 11] x = [3 4 1 0] print crt(m x)
using System; using System.Collections; using System.Collections.Generic; using System.Linq; // C# program to combine modular equations // using Chinese Remainder Theorem class HelloWorld { // function that implements Extended euclidean // algorithm public static List<int> extended_euclidean(int aint b){ if(a == 0){ List<int> temp = new List<int>(); temp.Add(b); temp.Add(0); temp.Add(1); return temp; } else{ List<int> temp = new List<int>(); temp.Add(0); temp.Add(0); temp.Add(0); temp= extended_euclidean(b % a a); int g = temp[0]; int y = temp[1]; int x = temp[2]; temp[0] = g; temp[1] = x - ((b/a) * y); temp[2] = y; return temp; } List<int> temp1 = new List<int>(); return temp1; } // modular inverse driver function public static double modinv(int aint m){ List<int> temp = new List<int>(); temp.Add(0); temp.Add(0); temp.Add(0); temp = extended_euclidean(a m); int g = temp[0]; int x = temp[1]; int y = temp[2]; // Since we are taking the modulo of // negative numbers so to have positive // output of the modulo we use this formula. double val = Math.Floor(((double)x/(double)m)); double ans = x - (val * m); return ans; } // function implementing Chinese remainder theorem // list m contains all the modulii // list x contains the remainders of the equations public static int crt(List<int> mList<int> x) { // We run this loop while the list of // remainders has length greater than 1 while(true) { // temp1 will contain the new value // of A. which is calculated according // to the equation m1' * m1 * x0 + m0' // * m0 * x1 double var1 = (modinv(m[1]m[0])); double var2 = (modinv(m[0]m[1])); // cout << var1 << ' ' << var2 << endl; double temp1 = (modinv(m[1]m[0])) * x[0] * m[1] + (modinv(m[0]m[1]) )* x[1] * m[0]; // temp2 contains the value of the modulus // in the new equation which will be the // product of the modulii of the two // equations that we are combining int temp2 = m[0] * m[1]; // cout << temp1<< ' '< // we then remove the first two elements // from the list of remainders and replace // it with the remainder value which will // be temp1 % temp2 x.RemoveAt(0); x.RemoveAt(0); x.Insert(0 (int)temp1%(int)temp2); //we then remove the first two values from //the list of modulii as we no longer require // them and simply replace them with the new // modulii that we calculated m.RemoveAt(0); m.RemoveAt(0); m.Insert(0 temp2); // once the list has only one element left // we can break as it will only contain // the value of our final remainder if(x.Count == 1){ break; } } // returns the remainder of the final equation return x[0]; } static void Main() { List<int> m = new List<int>(){ 4 7 9 11 }; List<int> x = new List<int> (){ 3 4 1 0 }; Console.WriteLine(crt(m x)); } } // The code is contributed by Nidhi goel.
// JavaScript program to combine modular equations // using Chinese Remainder Theorem // function that implements Extended euclidean // algorithm function extended_euclidean(a b){ if(a == 0){ let temp = [b 0 1]; return temp; } else{ let temp= extended_euclidean(b % a a); let g = temp[0]; let y = temp[1]; let x = temp[2]; temp[0] = g; temp[1] = x - (Math.floor(b/a) * y); temp[2] = y; return temp; } let temp; return temp; } // modular inverse driver function function modinv(a m){ let temp = extended_euclidean(a m); let g = temp[0]; let x = temp[1]; let y = temp[2]; // Since we are taking the modulo of // negative numbers so to have positive // output of the modulo we use this formula. let ans = x - (Math.floor(x/m) * m); return ans; } // function implementing Chinese remainder theorem // list m contains all the modulii // list x contains the remainders of the equations function crt(m x) { // We run this loop while the list of // remainders has length greater than 1 while(1) { // temp1 will contain the new value // of A. which is calculated according // to the equation m1' * m1 * x0 + m0' // * m0 * x1 let var1 = (modinv(m[1]m[0])); let var2 = (modinv(m[0]m[1]) ); // cout << var1 << ' ' << var2 << endl; let temp1 = (modinv(m[1]m[0])) * x[0] * m[1] + (modinv(m[0]m[1]) )* x[1] * m[0]; // temp2 contains the value of the modulus // in the new equation which will be the // product of the modulii of the two // equations that we are combining let temp2 = m[0] * m[1]; // cout << temp1<< ' '< // we then remove the first two elements // from the list of remainders and replace // it with the remainder value which will // be temp1 % temp2 x.shift(); x.shift(); x.unshift(temp1 % temp2); //we then remove the first two values from //the list of modulii as we no longer require // them and simply replace them with the new // modulii that we calculated m.shift(); m.shift(); m.unshift(temp2); // once the list has only one element left // we can break as it will only contain // the value of our final remainder if(x.length== 1){ break; } } // returns the remainder of the final equation return x[0]; } // driver segment let m = [4 7 9 11]; let x = [3 4 1 0]; console.log(crt(m x)); // The code is contributed by phasing17
Ausgabe:
1243
Zeitkomplexität: O(l) wobei l die Größe der Restliste ist.
Raumkomplexität: O(1), da wir keinen zusätzlichen Platz verbrauchen.
Dieser Satz und Algorithmus findet hervorragende Anwendungsmöglichkeiten. Eine sehr nützliche Anwendung ist das RechnenNCR% m wobei m keine Primzahl ist und Lucas-Theorem nicht direkt anwendbar. In einem solchen Fall können wir die Primfaktoren von m berechnen und die Primfaktoren einzeln als Modul in unserem verwendenNCR%m-Gleichung, die wir mit dem Lucas-Theorem berechnen und dann die resultierenden Gleichungen unter Verwendung des oben gezeigten chinesischen Restsatzes kombinieren können.
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