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solution.java
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solution.java
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import java.util.Scanner;
import java.util.Arrays;
// An "int" or "long" is not big enough to store big numbers. But Java's BigInteger is big enough.
public class Solution {
public static void main(String[] args) {
/* Read and save input */
Scanner sc = new Scanner(System.in);
String strL = new BigInt(sc.next()).subtract(BigInt.ONE).toString(); // subtract 1 since it's [L,R] inclusive
String strR = sc.next();
sc.close();
// Calculate interval sizes
int [] intervalDigits = new int[log2(strR.length()) + 3]; // The +3 gives us an estimate of the size we need
for (int k = 0; k < intervalDigits.length; k++) {
intervalDigits[k] = digitsInInterval(k);
}
// Initialize variables
StringBuilder sb = new StringBuilder();
int endL = strL.length();
int endR = strR.length();
BigInt upperBound = BigInt.ONE;
boolean carry = false;
boolean lastIteration = false;
int blockCount = 0;
int level = 0;
// Calculate counts for increasing segment sizes
while (!lastIteration) {
// Get portion of each String corresponding to current level
int numDigits = intervalDigits[level + 1] - intervalDigits[level];
int startL = Math.max(endL - numDigits, 0);
int startR = Math.max(endR - numDigits, 0);
BigInt numL = (endL == 0) ? BigInt.ZERO : new BigInt(strL.substring(startL, endL));
if (carry) {
numL = numL.add(BigInt.ONE);
}
// Calculate upper bound
if (startR == 0) {
upperBound = new BigInt(strR.substring(startR, endR));
lastIteration = true;
} else {
upperBound = BigInt.tenToPower(numDigits);
}
// If not skipping this level, process it
if ((!numL.equals(BigInt.ZERO) && !numL.equals(upperBound)) || startR == 0) {
BigInt count = upperBound.subtract(numL);
carry = true;
blockCount++;
sb.append(level + " " + count + "\n");
}
// Update variables for next iteration
endL = startL;
endR = startR;
level++;
}
StringBuilder sb2 = new StringBuilder();
level = 0;
endR = strR.length();
// Calculate counts for decreasing segment sizes
while (true) {
// Calculate number of nodes in current level
int numDigits = intervalDigits[level + 1] - intervalDigits[level];
int startR = Math.max(endR - numDigits, 0);
if (startR == 0) {
break;
}
BigInt count = new BigInt(strR.substring(startR, endR));
// If not skipping this level, process it
if (!count.equals(BigInt.ZERO)) {
blockCount++;
sb2.insert(0, level + " " + count + "\n");
}
// Update variables for next iteration
endR = startR;
level++;
}
System.out.println(blockCount + "\n" + sb + sb2);
}
static int log2(int n) { // assumes positive number
return 31 - Integer.numberOfLeadingZeros(n);
}
static int digitsInInterval(int k) {
if (k == 0) {
return 1;
} else {
return (int) (Math.pow(2, k - 1) + 1);
}
}
}
// BigInt numbers may be stored with leading 0s
// BigInt only works with non-negative integers
class BigInt {
public static final BigInt ZERO = new BigInt("0");
public static final BigInt ONE = new BigInt("1");
public final byte[] digits; // will use 8 bits per digit for simplicity, even though 4 bits is enough
// Constructor
public BigInt(String str) {
digits = new byte[str.length()];
for (int i = 0; i < digits.length; i++) {
digits[i] = Byte.valueOf(str.substring(i, i + 1));
}
}
// Constructor
public BigInt(byte [] digits) {
this.digits = digits;
}
public static BigInt tenToPower(int exponent) {
byte [] digits = new byte[exponent + 1];
digits[0] = 1;
return new BigInt(digits);
}
public BigInt add(BigInt other) {
byte [] digitsA = digits;
byte [] digitsB = other.digits;
// Create new Array to hold answer
int newLength = Math.max(digitsA.length, digitsB.length);
if (!(digitsA[0] == 0 && digitsB[0] == 0)) {
newLength++;
}
byte [] result = new byte[newLength];
// Do the addition
int carry = 0;
int ptrA = digitsA.length - 1;
int ptrB = digitsB.length - 1;
int ptrR = result.length - 1;
while (ptrA >= 0 || ptrB >= 0 || carry > 0) {
int sum = carry;
if (ptrA >= 0) {
sum += digitsA[ptrA--];
}
if (ptrB >= 0) {
sum += digitsB[ptrB--];
}
result[ptrR--] = (byte) (sum % 10);
carry = sum / 10;
}
return new BigInt(result);
}
public BigInt subtract(BigInt other) { // assumes "other" is smaller than this BigInt
byte [] digitsB = other.digits;
byte [] result = Arrays.copyOf(digits, digits.length); // copy of "digitsA"
// Do the subtraction
int ptrB = digitsB.length - 1;
int ptrR = result.length - 1;
while (ptrB >= 0 && ptrR >= 0) {
result[ptrR] -= digitsB[ptrB];
// if necessary, do the "borrow"
if (result[ptrR] < 0) {
result[ptrR] += 10;
int ptrBorrow = ptrR - 1;
while (result[ptrBorrow] == 0) {
result[ptrBorrow--] = 9;
}
result[ptrBorrow]--;
}
ptrB--;
ptrR--;
}
return new BigInt(result);
}
@Override
public boolean equals(Object other) {
if (!(other instanceof BigInt)) {
return false;
}
byte [] digitsA = digits;
byte [] digitsB = ((BigInt) other).digits;
int indexA = 0;
int indexB = 0;
// Remove leading 0s
while (indexA < digitsA.length && digitsA[indexA] == 0) {
indexA++;
}
while (indexB < digitsB.length && digitsB[indexB] == 0) {
indexB++;
}
int lenA = digitsA.length - indexA;
int lenB = digitsB.length - indexB;
if (lenA != lenB) {
return false;
}
// Check to see if all digits match for the 2 BigInts
while (indexA < digitsA.length && indexB < digitsB.length) {
if (digitsA[indexA++] != digitsB[indexB++]) {
return false;
}
}
return true;
}
@Override
public String toString() {
StringBuilder sb = new StringBuilder();
int i = 0;
// Skip leading 0s
while (i < digits.length && digits[i] == 0) {
i++;
}
// Special Case: the BigInt 0
if (i == digits.length) {
return "0";
}
// Create and return String
for ( ; i < digits.length; i++) {
sb.append(digits[i]);
}
return sb.toString();
}
}