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337 lines
12 KiB
Solidity
337 lines
12 KiB
Solidity
2 years ago
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// SPDX-License-Identifier: MIT
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// OpenZeppelin Contracts (last updated v4.8.0) (utils/math/Math.sol)
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pragma solidity ^0.8.0;
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/**
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* @dev Standard math utilities missing in the Solidity language.
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*/
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library Math {
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enum Rounding {
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Down, // Toward negative infinity
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Up, // Toward infinity
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Zero // Toward zero
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}
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/**
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* @dev Returns the largest of two numbers.
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*/
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function max(uint256 a, uint256 b) internal pure returns (uint256) {
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return a > b ? a : b;
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}
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/**
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* @dev Returns the smallest of two numbers.
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*/
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function min(uint256 a, uint256 b) internal pure returns (uint256) {
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return a < b ? a : b;
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}
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/**
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* @dev Returns the average of two numbers. The result is rounded towards
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* zero.
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*/
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function average(uint256 a, uint256 b) internal pure returns (uint256) {
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// (a + b) / 2 can overflow.
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return (a & b) + (a ^ b) / 2;
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}
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/**
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* @dev Returns the ceiling of the division of two numbers.
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*
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* This differs from standard division with `/` in that it rounds up instead
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* of rounding down.
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*/
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function ceilDiv(uint256 a, uint256 b) internal pure returns (uint256) {
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// (a + b - 1) / b can overflow on addition, so we distribute.
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return a == 0 ? 0 : (a - 1) / b + 1;
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}
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/**
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* @notice Calculates floor(x * y / denominator) with full precision. Throws if result overflows a uint256 or denominator == 0
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* @dev Original credit to Remco Bloemen under MIT license (https://xn--2-umb.com/21/muldiv)
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* with further edits by Uniswap Labs also under MIT license.
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*/
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function mulDiv(uint256 x, uint256 y, uint256 denominator) internal pure returns (uint256 result) {
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unchecked {
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// 512-bit multiply [prod1 prod0] = x * y. Compute the product mod 2^256 and mod 2^256 - 1, then use
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// use the Chinese Remainder Theorem to reconstruct the 512 bit result. The result is stored in two 256
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// variables such that product = prod1 * 2^256 + prod0.
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uint256 prod0; // Least significant 256 bits of the product
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uint256 prod1; // Most significant 256 bits of the product
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assembly {
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let mm := mulmod(x, y, not(0))
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prod0 := mul(x, y)
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prod1 := sub(sub(mm, prod0), lt(mm, prod0))
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}
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// Handle non-overflow cases, 256 by 256 division.
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if (prod1 == 0) {
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return prod0 / denominator;
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}
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// Make sure the result is less than 2^256. Also prevents denominator == 0.
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require(denominator > prod1, "Math: mulDiv overflow");
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///////////////////////////////////////////////
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// 512 by 256 division.
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///////////////////////////////////////////////
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// Make division exact by subtracting the remainder from [prod1 prod0].
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uint256 remainder;
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assembly {
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// Compute remainder using mulmod.
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remainder := mulmod(x, y, denominator)
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// Subtract 256 bit number from 512 bit number.
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prod1 := sub(prod1, gt(remainder, prod0))
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prod0 := sub(prod0, remainder)
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}
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// Factor powers of two out of denominator and compute largest power of two divisor of denominator. Always >= 1.
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// See https://cs.stackexchange.com/q/138556/92363.
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// Does not overflow because the denominator cannot be zero at this stage in the function.
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uint256 twos = denominator & (~denominator + 1);
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assembly {
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// Divide denominator by twos.
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denominator := div(denominator, twos)
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// Divide [prod1 prod0] by twos.
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prod0 := div(prod0, twos)
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// Flip twos such that it is 2^256 / twos. If twos is zero, then it becomes one.
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twos := add(div(sub(0, twos), twos), 1)
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}
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// Shift in bits from prod1 into prod0.
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prod0 |= prod1 * twos;
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// Invert denominator mod 2^256. Now that denominator is an odd number, it has an inverse modulo 2^256 such
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// that denominator * inv = 1 mod 2^256. Compute the inverse by starting with a seed that is correct for
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// four bits. That is, denominator * inv = 1 mod 2^4.
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uint256 inverse = (3 * denominator) ^ 2;
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// Use the Newton-Raphson iteration to improve the precision. Thanks to Hensel's lifting lemma, this also works
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// in modular arithmetic, doubling the correct bits in each step.
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inverse *= 2 - denominator * inverse; // inverse mod 2^8
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inverse *= 2 - denominator * inverse; // inverse mod 2^16
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inverse *= 2 - denominator * inverse; // inverse mod 2^32
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inverse *= 2 - denominator * inverse; // inverse mod 2^64
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inverse *= 2 - denominator * inverse; // inverse mod 2^128
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inverse *= 2 - denominator * inverse; // inverse mod 2^256
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// Because the division is now exact we can divide by multiplying with the modular inverse of denominator.
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// This will give us the correct result modulo 2^256. Since the preconditions guarantee that the outcome is
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// less than 2^256, this is the final result. We don't need to compute the high bits of the result and prod1
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// is no longer required.
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result = prod0 * inverse;
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return result;
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}
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}
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/**
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* @notice Calculates x * y / denominator with full precision, following the selected rounding direction.
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*/
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function mulDiv(uint256 x, uint256 y, uint256 denominator, Rounding rounding) internal pure returns (uint256) {
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uint256 result = mulDiv(x, y, denominator);
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if (rounding == Rounding.Up && mulmod(x, y, denominator) > 0) {
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result += 1;
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}
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return result;
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}
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/**
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* @dev Returns the square root of a number. If the number is not a perfect square, the value is rounded down.
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*
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* Inspired by Henry S. Warren, Jr.'s "Hacker's Delight" (Chapter 11).
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*/
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function sqrt(uint256 a) internal pure returns (uint256) {
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if (a == 0) {
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return 0;
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}
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// For our first guess, we get the biggest power of 2 which is smaller than the square root of the target.
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//
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// We know that the "msb" (most significant bit) of our target number `a` is a power of 2 such that we have
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// `msb(a) <= a < 2*msb(a)`. This value can be written `msb(a)=2**k` with `k=log2(a)`.
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//
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// This can be rewritten `2**log2(a) <= a < 2**(log2(a) + 1)`
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// → `sqrt(2**k) <= sqrt(a) < sqrt(2**(k+1))`
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// → `2**(k/2) <= sqrt(a) < 2**((k+1)/2) <= 2**(k/2 + 1)`
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//
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// Consequently, `2**(log2(a) / 2)` is a good first approximation of `sqrt(a)` with at least 1 correct bit.
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uint256 result = 1 << (log2(a) >> 1);
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// At this point `result` is an estimation with one bit of precision. We know the true value is a uint128,
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// since it is the square root of a uint256. Newton's method converges quadratically (precision doubles at
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// every iteration). We thus need at most 7 iteration to turn our partial result with one bit of precision
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// into the expected uint128 result.
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unchecked {
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result = (result + a / result) >> 1;
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result = (result + a / result) >> 1;
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result = (result + a / result) >> 1;
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result = (result + a / result) >> 1;
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result = (result + a / result) >> 1;
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result = (result + a / result) >> 1;
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result = (result + a / result) >> 1;
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return min(result, a / result);
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}
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}
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/**
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* @notice Calculates sqrt(a), following the selected rounding direction.
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*/
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function sqrt(uint256 a, Rounding rounding) internal pure returns (uint256) {
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unchecked {
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uint256 result = sqrt(a);
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return result + (rounding == Rounding.Up && result * result < a ? 1 : 0);
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}
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}
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/**
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* @dev Return the log in base 2, rounded down, of a positive value.
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* Returns 0 if given 0.
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*/
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function log2(uint256 value) internal pure returns (uint256) {
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uint256 result = 0;
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unchecked {
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if (value >> 128 > 0) {
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value >>= 128;
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result += 128;
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}
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if (value >> 64 > 0) {
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value >>= 64;
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result += 64;
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}
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if (value >> 32 > 0) {
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value >>= 32;
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result += 32;
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}
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if (value >> 16 > 0) {
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value >>= 16;
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result += 16;
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}
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if (value >> 8 > 0) {
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value >>= 8;
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result += 8;
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}
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if (value >> 4 > 0) {
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value >>= 4;
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result += 4;
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}
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if (value >> 2 > 0) {
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value >>= 2;
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result += 2;
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}
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if (value >> 1 > 0) {
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result += 1;
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}
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}
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return result;
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}
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/**
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* @dev Return the log in base 2, following the selected rounding direction, of a positive value.
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* Returns 0 if given 0.
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*/
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function log2(uint256 value, Rounding rounding) internal pure returns (uint256) {
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unchecked {
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uint256 result = log2(value);
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return result + (rounding == Rounding.Up && 1 << result < value ? 1 : 0);
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}
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}
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/**
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* @dev Return the log in base 10, rounded down, of a positive value.
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* Returns 0 if given 0.
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*/
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function log10(uint256 value) internal pure returns (uint256) {
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uint256 result = 0;
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unchecked {
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if (value >= 10 ** 64) {
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value /= 10 ** 64;
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result += 64;
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}
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if (value >= 10 ** 32) {
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value /= 10 ** 32;
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result += 32;
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}
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if (value >= 10 ** 16) {
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value /= 10 ** 16;
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result += 16;
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}
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if (value >= 10 ** 8) {
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value /= 10 ** 8;
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result += 8;
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}
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if (value >= 10 ** 4) {
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value /= 10 ** 4;
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result += 4;
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}
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if (value >= 10 ** 2) {
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value /= 10 ** 2;
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result += 2;
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}
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if (value >= 10 ** 1) {
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result += 1;
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}
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}
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return result;
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}
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/**
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* @dev Return the log in base 10, following the selected rounding direction, of a positive value.
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* Returns 0 if given 0.
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*/
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function log10(uint256 value, Rounding rounding) internal pure returns (uint256) {
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unchecked {
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uint256 result = log10(value);
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return result + (rounding == Rounding.Up && 10 ** result < value ? 1 : 0);
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}
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}
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/**
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* @dev Return the log in base 256, rounded down, of a positive value.
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* Returns 0 if given 0.
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*
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* Adding one to the result gives the number of pairs of hex symbols needed to represent `value` as a hex string.
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*/
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function log256(uint256 value) internal pure returns (uint256) {
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uint256 result = 0;
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unchecked {
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if (value >> 128 > 0) {
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value >>= 128;
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result += 16;
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}
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if (value >> 64 > 0) {
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value >>= 64;
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result += 8;
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}
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if (value >> 32 > 0) {
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value >>= 32;
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result += 4;
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}
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if (value >> 16 > 0) {
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value >>= 16;
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result += 2;
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}
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if (value >> 8 > 0) {
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result += 1;
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}
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}
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return result;
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}
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/**
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* @dev Return the log in base 256, following the selected rounding direction, of a positive value.
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* Returns 0 if given 0.
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*/
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function log256(uint256 value, Rounding rounding) internal pure returns (uint256) {
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unchecked {
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uint256 result = log256(value);
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return result + (rounding == Rounding.Up && 1 << (result << 3) < value ? 1 : 0);
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}
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}
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}
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