kassandraoftroy/gist:9c14ce530bf297d7c04e657ce8341b94

## gistfile1.txt
// SPDX-License-Identifier: GPL-2.0-or-later
pragma solidity >=0.8.0;

/// @title Contains 512-bit math functions
/// @notice Facilitates multiplication and division that can have overflow of an intermediate value without any loss of precision
/// @dev Handles "phantom overflow" i.e., allows multiplication and division where an intermediate value overflows 256 bits
library FullMath {
    /// @notice Calculates floor(a×b÷denominator) with full precision. Throws if result overflows a uint256 or denominator == 0
    /// @param a The multiplicand
    /// @param b The multiplier
    /// @param denominator The divisor
    /// @return result The 256-bit result
    /// @dev Credit to Remco Bloemen under MIT license https://xn--2-umb.com/21/muldiv
    function mulDiv(
        uint256 a,
        uint256 b,
        uint256 denominator
    ) internal pure returns (uint256 result) {
        unchecked {
            // 512-bit multiply [prod1 prod0] = a * b
            // Compute the product mod 2**256 and mod 2**256 - 1
            // then use the Chinese Remainder Theorem to reconstruct
            // the 512 bit result. The result is stored in two 256
            // variables such that product = prod1 * 2**256 + prod0
            uint256 prod0; // Least significant 256 bits of the product
            uint256 prod1; // Most significant 256 bits of the product
            assembly {
                let mm := mulmod(a, b, not(0))
                prod0 := mul(a, b)
                prod1 := sub(sub(mm, prod0), lt(mm, prod0))
            }

            // Handle non-overflow cases, 256 by 256 division
            if (prod1 == 0) {
                require(denominator > 0);
                assembly {
                    result := div(prod0, denominator)
                }
                return result;
            }

            // Make sure the result is less than 2**256.
            // Also prevents denominator == 0
            require(denominator > prod1);

            ///////////////////////////////////////////////
            // 512 by 256 division.
            ///////////////////////////////////////////////

            // Make division exact by subtracting the remainder from [prod1 prod0]
            // Compute remainder using mulmod
            uint256 remainder;
            assembly {
                remainder := mulmod(a, b, denominator)
            }
            // Subtract 256 bit number from 512 bit number
            assembly {
                prod1 := sub(prod1, gt(remainder, prod0))
                prod0 := sub(prod0, remainder)
            }

            // Factor powers of two out of denominator
            // Compute largest power of two divisor of denominator.
            // Always >= 1.
            // EDIT for 0.8 compatibility:
            // see: https://ethereum.stackexchange.com/questions/96642/unary-operator-cannot-be-applied-to-type-uint256
            uint256 twos = denominator & (~denominator + 1);

            // Divide denominator by power of two
            assembly {
                denominator := div(denominator, twos)
            }

            // Divide [prod1 prod0] by the factors of two
            assembly {
                prod0 := div(prod0, twos)
            }
            // Shift in bits from prod1 into prod0. For this we need
            // to flip `twos` such that it is 2**256 / twos.
            // If twos is zero, then it becomes one
            assembly {
                twos := add(div(sub(0, twos), twos), 1)
            }
            prod0 |= prod1 * twos;

            // Invert denominator mod 2**256
            // Now that denominator is an odd number, it has an inverse
            // modulo 2**256 such that denominator * inv = 1 mod 2**256.
            // Compute the inverse by starting with a seed that is correct
            // correct for four bits. That is, denominator * inv = 1 mod 2**4
            uint256 inv = (3 * denominator) ^ 2;
            // Now use Newton-Raphson iteration to improve the precision.
            // Thanks to Hensel's lifting lemma, this also works in modular
            // arithmetic, doubling the correct bits in each step.
            inv *= 2 - denominator * inv; // inverse mod 2**8
            inv *= 2 - denominator * inv; // inverse mod 2**16
            inv *= 2 - denominator * inv; // inverse mod 2**32
            inv *= 2 - denominator * inv; // inverse mod 2**64
            inv *= 2 - denominator * inv; // inverse mod 2**128
            inv *= 2 - denominator * inv; // inverse mod 2**256

            // Because the division is now exact we can divide by multiplying
            // with the modular inverse of denominator. This will give us the
            // correct result modulo 2**256. Since the precoditions guarantee
            // that the outcome is less than 2**256, this is the final result.
            // We don't need to compute the high bits of the result and prod1
            // is no longer required.
            result = prod0 * inv;
            return result;
        }
    }

    /// @notice Calculates ceil(a×b÷denominator) with full precision. Throws if result overflows a uint256 or denominator == 0
    /// @param a The multiplicand
    /// @param b The multiplier
    /// @param denominator The divisor
    /// @return result The 256-bit result
    function mulDivRoundingUp(
        uint256 a,
        uint256 b,
        uint256 denominator
    ) internal pure returns (uint256 result) {
        result = mulDiv(a, b, denominator);
        if (mulmod(a, b, denominator) > 0) {
            require(result < type(uint256).max);
            result++;
        }
    }
}
	// SPDX-License-Identifier: GPL-2.0-or-later
	pragma solidity >=0.8.0;

	/// @title Contains 512-bit math functions
	/// @notice Facilitates multiplication and division that can have overflow of an intermediate value without any loss of precision
	/// @dev Handles "phantom overflow" i.e., allows multiplication and division where an intermediate value overflows 256 bits
	library FullMath {
	/// @notice Calculates floor(a×b÷denominator) with full precision. Throws if result overflows a uint256 or denominator == 0
	/// @param a The multiplicand
	/// @param b The multiplier
	/// @param denominator The divisor
	/// @return result The 256-bit result
	/// @dev Credit to Remco Bloemen under MIT license https://xn--2-umb.com/21/muldiv
	function mulDiv(
	uint256 a,
	uint256 b,
	uint256 denominator
	) internal pure returns (uint256 result) {
	unchecked {
	// 512-bit multiply [prod1 prod0] = a * b
	// Compute the product mod 2256 and mod 2256 - 1
	// then use the Chinese Remainder Theorem to reconstruct
	// the 512 bit result. The result is stored in two 256
	// variables such that product = prod1 * 2**256 + prod0
	uint256 prod0; // Least significant 256 bits of the product
	uint256 prod1; // Most significant 256 bits of the product
	assembly {
	let mm := mulmod(a, b, not(0))
	prod0 := mul(a, b)
	prod1 := sub(sub(mm, prod0), lt(mm, prod0))
	}

	// Handle non-overflow cases, 256 by 256 division
	if (prod1 == 0) {
	require(denominator > 0);
	assembly {
	result := div(prod0, denominator)
	}
	return result;
	}

	// Make sure the result is less than 2**256.
	// Also prevents denominator == 0
	require(denominator > prod1);

	///////////////////////////////////////////////
	// 512 by 256 division.
	///////////////////////////////////////////////

	// Make division exact by subtracting the remainder from [prod1 prod0]
	// Compute remainder using mulmod
	uint256 remainder;
	assembly {
	remainder := mulmod(a, b, denominator)
	}
	// Subtract 256 bit number from 512 bit number
	assembly {
	prod1 := sub(prod1, gt(remainder, prod0))
	prod0 := sub(prod0, remainder)
	}

	// Factor powers of two out of denominator
	// Compute largest power of two divisor of denominator.
	// Always >= 1.
	// EDIT for 0.8 compatibility:
	// see: https://ethereum.stackexchange.com/questions/96642/unary-operator-cannot-be-applied-to-type-uint256
	uint256 twos = denominator & (~denominator + 1);

	// Divide denominator by power of two
	assembly {
	denominator := div(denominator, twos)
	}

	// Divide [prod1 prod0] by the factors of two
	assembly {
	prod0 := div(prod0, twos)
	}
	// Shift in bits from prod1 into prod0. For this we need
	// to flip `twos` such that it is 2**256 / twos.
	// If twos is zero, then it becomes one
	assembly {
	twos := add(div(sub(0, twos), twos), 1)
	}
	prod0 \|= prod1 * twos;

	// Invert denominator mod 2**256
	// Now that denominator is an odd number, it has an inverse
	// modulo 2*256 such that denominator inv = 1 mod 2**256.
	// Compute the inverse by starting with a seed that is correct
	// correct for four bits. That is, denominator * inv = 1 mod 2**4
	uint256 inv = (3 * denominator) ^ 2;
	// Now use Newton-Raphson iteration to improve the precision.
	// Thanks to Hensel's lifting lemma, this also works in modular
	// arithmetic, doubling the correct bits in each step.
	inv = 2 - denominator inv; // inverse mod 2**8
	inv = 2 - denominator inv; // inverse mod 2**16
	inv = 2 - denominator inv; // inverse mod 2**32
	inv = 2 - denominator inv; // inverse mod 2**64
	inv = 2 - denominator inv; // inverse mod 2**128
	inv = 2 - denominator inv; // inverse mod 2**256

	// Because the division is now exact we can divide by multiplying
	// with the modular inverse of denominator. This will give us the
	// correct result modulo 2**256. Since the precoditions guarantee
	// that the outcome is less than 2**256, this is the final result.
	// We don't need to compute the high bits of the result and prod1
	// is no longer required.
	result = prod0 * inv;
	return result;
	}
	}

	/// @notice Calculates ceil(a×b÷denominator) with full precision. Throws if result overflows a uint256 or denominator == 0
	/// @param a The multiplicand
	/// @param b The multiplier
	/// @param denominator The divisor
	/// @return result The 256-bit result
	function mulDivRoundingUp(
	uint256 a,
	uint256 b,
	uint256 denominator
	) internal pure returns (uint256 result) {
	result = mulDiv(a, b, denominator);
	if (mulmod(a, b, denominator) > 0) {
	require(result < type(uint256).max);
	result++;
	}
	}
	}