/** @file * IPRT - RTUINT256U methods. */ /* * Copyright (C) 2011-2022 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. * * The contents of this file may alternatively be used under the terms * of the Common Development and Distribution License Version 1.0 * (CDDL) only, as it comes in the "COPYING.CDDL" file of the * VirtualBox OSE distribution, in which case the provisions of the * CDDL are applicable instead of those of the GPL. * * You may elect to license modified versions of this file under the * terms and conditions of either the GPL or the CDDL or both. */ #ifndef IPRT_INCLUDED_uint256_h #define IPRT_INCLUDED_uint256_h #ifndef RT_WITHOUT_PRAGMA_ONCE # pragma once #endif #include #include #include #include RT_C_DECLS_BEGIN /** @defgroup grp_rt_uint256 RTUInt256 - 256-bit Unsigned Integer Methods * @ingroup grp_rt * @{ */ /** * Test if a 256-bit unsigned integer value is zero. * * @returns true if they are, false if they aren't. * @param pValue The input and output value. */ DECLINLINE(bool) RTUInt256IsZero(PCRTUINT256U pValue) { #if ARCH_BITS >= 64 return pValue->QWords.qw0 == 0 && pValue->QWords.qw1 == 0 && pValue->QWords.qw2 == 0 && pValue->QWords.qw3 == 0; #else return pValue->DWords.dw0 == 0 && pValue->DWords.dw1 == 0 && pValue->DWords.dw2 == 0 && pValue->DWords.dw3 == 0 && pValue->DWords.dw4 == 0 && pValue->DWords.dw5 == 0 && pValue->DWords.dw6 == 0 && pValue->DWords.dw7 == 0; #endif } /** * Set a 256-bit unsigned integer value to zero. * * @returns pResult * @param pResult The result variable. */ DECLINLINE(PRTUINT256U) RTUInt256SetZero(PRTUINT256U pResult) { #if ARCH_BITS >= 64 pResult->QWords.qw0 = 0; pResult->QWords.qw1 = 0; pResult->QWords.qw2 = 0; pResult->QWords.qw3 = 0; #else pResult->DWords.dw0 = 0; pResult->DWords.dw1 = 0; pResult->DWords.dw2 = 0; pResult->DWords.dw3 = 0; pResult->DWords.dw4 = 0; pResult->DWords.dw5 = 0; pResult->DWords.dw6 = 0; pResult->DWords.dw7 = 0; #endif return pResult; } /** * Set a 256-bit unsigned integer value to the maximum value. * * @returns pResult * @param pResult The result variable. */ DECLINLINE(PRTUINT256U) RTUInt256SetMax(PRTUINT256U pResult) { #if ARCH_BITS >= 64 pResult->QWords.qw0 = UINT64_MAX; pResult->QWords.qw1 = UINT64_MAX; pResult->QWords.qw2 = UINT64_MAX; pResult->QWords.qw3 = UINT64_MAX; #else pResult->DWords.dw0 = UINT32_MAX; pResult->DWords.dw1 = UINT32_MAX; pResult->DWords.dw2 = UINT32_MAX; pResult->DWords.dw3 = UINT32_MAX; pResult->DWords.dw4 = UINT32_MAX; pResult->DWords.dw5 = UINT32_MAX; pResult->DWords.dw6 = UINT32_MAX; pResult->DWords.dw7 = UINT32_MAX; #endif return pResult; } /** * Adds two 256-bit unsigned integer values. * * @returns pResult * @param pResult The result variable. * @param pValue1 The first value. * @param pValue2 The second value. */ DECLINLINE(PRTUINT256U) RTUInt256Add(PRTUINT256U pResult, PCRTUINT256U pValue1, PCRTUINT256U pValue2) { unsigned uCarry; pResult->QWords.qw0 = pValue1->QWords.qw0 + pValue2->QWords.qw0; uCarry = pResult->QWords.qw0 < pValue1->QWords.qw0; pResult->QWords.qw1 = pValue1->QWords.qw1 + pValue2->QWords.qw1 + uCarry; uCarry = uCarry ? pResult->QWords.qw1 <= pValue1->QWords.qw1 : pResult->QWords.qw1 < pValue1->QWords.qw1; pResult->QWords.qw2 = pValue1->QWords.qw2 + pValue2->QWords.qw2 + uCarry; uCarry = uCarry ? pResult->QWords.qw2 <= pValue1->QWords.qw2 : pResult->QWords.qw2 < pValue1->QWords.qw2; pResult->QWords.qw3 = pValue1->QWords.qw3 + pValue2->QWords.qw3 + uCarry; return pResult; } /** * Adds a 256-bit and a 64-bit unsigned integer values. * * @returns pResult * @param pResult The result variable. * @param pValue1 The first value. * @param uValue2 The second value, 64-bit. */ DECLINLINE(PRTUINT256U) RTUInt256AddU64(PRTUINT256U pResult, PCRTUINT256U pValue1, uint64_t uValue2) { pResult->QWords.qw3 = pValue1->QWords.qw3; pResult->QWords.qw2 = pValue1->QWords.qw2; pResult->QWords.qw1 = pValue1->QWords.qw1; pResult->QWords.qw0 = pValue1->QWords.qw0 + uValue2; if (pResult->QWords.qw0 < uValue2) if (pResult->QWords.qw1++ == UINT64_MAX) if (pResult->QWords.qw2++ == UINT64_MAX) pResult->QWords.qw3++; return pResult; } /** * Subtracts a 256-bit unsigned integer value from another. * * @returns pResult * @param pResult The result variable. * @param pValue1 The minuend value. * @param pValue2 The subtrahend value. */ DECLINLINE(PRTUINT256U) RTUInt256Sub(PRTUINT256U pResult, PCRTUINT256U pValue1, PCRTUINT256U pValue2) { unsigned uBorrow; pResult->QWords.qw0 = pValue1->QWords.qw0 - pValue2->QWords.qw0; uBorrow = pResult->QWords.qw0 > pValue1->QWords.qw0; pResult->QWords.qw1 = pValue1->QWords.qw1 - pValue2->QWords.qw1 - uBorrow; uBorrow = uBorrow ? pResult->QWords.qw1 >= pValue1->QWords.qw1 : pResult->QWords.qw1 > pValue1->QWords.qw1; pResult->QWords.qw2 = pValue1->QWords.qw2 - pValue2->QWords.qw2 - uBorrow; uBorrow = uBorrow ? pResult->QWords.qw2 >= pValue1->QWords.qw2 : pResult->QWords.qw2 > pValue1->QWords.qw2; pResult->QWords.qw3 = pValue1->QWords.qw3 - pValue2->QWords.qw3 - uBorrow; return pResult; } /** * Multiplies two 256-bit unsigned integer values. * * @returns pResult * @param pResult The result variable. * @param pValue1 The first value. * @param pValue2 The second value. */ RTDECL(PRTUINT256U) RTUInt256Mul(PRTUINT256U pResult, PCRTUINT256U pValue1, PCRTUINT256U pValue2); /** * Multiplies an 256-bit unsigned integer by a 64-bit unsigned integer value. * * @returns pResult * @param pResult The result variable. * @param pValue1 The first value. * @param uValue2 The second value, 64-bit. */ RTDECL(PRTUINT256U) RTUInt256MulByU64(PRTUINT256U pResult, PCRTUINT256U pValue1, uint64_t uValue2); /** * Divides a 256-bit unsigned integer value by another, returning both quotient * and remainder. * * @returns pQuotient, NULL if pValue2 is 0. * @param pQuotient Where to return the quotient. * @param pRemainder Where to return the remainder. * @param pValue1 The dividend value. * @param pValue2 The divisor value. */ RTDECL(PRTUINT256U) RTUInt256DivRem(PRTUINT256U pQuotient, PRTUINT256U pRemainder, PCRTUINT256U pValue1, PCRTUINT256U pValue2); /** * Divides a 256-bit unsigned integer value by another. * * @returns pResult * @param pResult The result variable. * @param pValue1 The dividend value. * @param pValue2 The divisor value. */ DECLINLINE(PRTUINT256U) RTUInt256Div(PRTUINT256U pResult, PCRTUINT256U pValue1, PCRTUINT256U pValue2) { RTUINT256U Ignored; return RTUInt256DivRem(pResult, &Ignored, pValue1, pValue2); } /** * Divides a 256-bit unsigned integer value by another, returning the remainder. * * @returns pResult * @param pResult The result variable (remainder). * @param pValue1 The dividend value. * @param pValue2 The divisor value. */ DECLINLINE(PRTUINT256U) RTUInt256Mod(PRTUINT256U pResult, PCRTUINT256U pValue1, PCRTUINT256U pValue2) { RTUINT256U Ignored; RTUInt256DivRem(&Ignored, pResult, pValue1, pValue2); return pResult; } /** * Bitwise AND of two 256-bit unsigned integer values. * * @returns pResult * @param pResult The result variable. * @param pValue1 The first value. * @param pValue2 The second value. */ DECLINLINE(PRTUINT256U) RTUInt256And(PRTUINT256U pResult, PCRTUINT256U pValue1, PCRTUINT256U pValue2) { pResult->QWords.qw0 = pValue1->QWords.qw0 & pValue2->QWords.qw0; pResult->QWords.qw1 = pValue1->QWords.qw1 & pValue2->QWords.qw1; pResult->QWords.qw2 = pValue1->QWords.qw2 & pValue2->QWords.qw2; pResult->QWords.qw3 = pValue1->QWords.qw3 & pValue2->QWords.qw3; return pResult; } /** * Bitwise OR of two 256-bit unsigned integer values. * * @returns pResult * @param pResult The result variable. * @param pValue1 The first value. * @param pValue2 The second value. */ DECLINLINE(PRTUINT256U) RTUInt256Or( PRTUINT256U pResult, PCRTUINT256U pValue1, PCRTUINT256U pValue2) { pResult->QWords.qw0 = pValue1->QWords.qw0 | pValue2->QWords.qw0; pResult->QWords.qw1 = pValue1->QWords.qw1 | pValue2->QWords.qw1; pResult->QWords.qw2 = pValue1->QWords.qw2 | pValue2->QWords.qw2; pResult->QWords.qw3 = pValue1->QWords.qw3 | pValue2->QWords.qw3; return pResult; } /** * Bitwise XOR of two 256-bit unsigned integer values. * * @returns pResult * @param pResult The result variable. * @param pValue1 The first value. * @param pValue2 The second value. */ DECLINLINE(PRTUINT256U) RTUInt256Xor(PRTUINT256U pResult, PCRTUINT256U pValue1, PCRTUINT256U pValue2) { pResult->QWords.qw0 = pValue1->QWords.qw0 ^ pValue2->QWords.qw0; pResult->QWords.qw1 = pValue1->QWords.qw1 ^ pValue2->QWords.qw1; pResult->QWords.qw2 = pValue1->QWords.qw2 ^ pValue2->QWords.qw2; pResult->QWords.qw3 = pValue1->QWords.qw3 ^ pValue2->QWords.qw3; return pResult; } /** * Shifts a 256-bit unsigned integer value @a cBits to the left. * * @returns pResult * @param pResult The result variable. * @param pValue The value to shift. * @param cBits The number of bits to shift it. This is masked * by 255 before shifting. */ DECLINLINE(PRTUINT256U) RTUInt256ShiftLeft(PRTUINT256U pResult, PCRTUINT256U pValue, unsigned cBits) { /* This is a bit bulky & impractical since we cannot access the data using an array because it is organized according to host endianness. Sigh. */ cBits &= 255; if (!(cBits & 0x3f)) { if (cBits == 0) *pResult = *pValue; else { pResult->QWords.qw0 = 0; if (cBits == 64) { pResult->QWords.qw1 = pValue->QWords.qw0; pResult->QWords.qw2 = pValue->QWords.qw1; pResult->QWords.qw3 = pValue->QWords.qw2; } else { pResult->QWords.qw1 = 0; if (cBits == 128) { pResult->QWords.qw2 = pValue->QWords.qw0; pResult->QWords.qw3 = pValue->QWords.qw1; } else { pResult->QWords.qw2 = 0; pResult->QWords.qw3 = pValue->QWords.qw0; } } } } else if (cBits < 128) { if (cBits < 64) { pResult->QWords.qw0 = pValue->QWords.qw0 << cBits; pResult->QWords.qw1 = pValue->QWords.qw0 >> (64 - cBits); pResult->QWords.qw1 |= pValue->QWords.qw1 << cBits; pResult->QWords.qw2 = pValue->QWords.qw1 >> (64 - cBits); pResult->QWords.qw2 |= pValue->QWords.qw2 << cBits; pResult->QWords.qw3 = pValue->QWords.qw2 >> (64 - cBits); pResult->QWords.qw3 |= pValue->QWords.qw3 << cBits; } else { cBits -= 64; pResult->QWords.qw0 = 0; pResult->QWords.qw1 = pValue->QWords.qw0 << cBits; pResult->QWords.qw2 = pValue->QWords.qw0 >> (64 - cBits); pResult->QWords.qw2 |= pValue->QWords.qw1 << cBits; pResult->QWords.qw3 = pValue->QWords.qw1 >> (64 - cBits); pResult->QWords.qw3 |= pValue->QWords.qw2 << cBits; } } else { if (cBits < 192) { cBits -= 128; pResult->QWords.qw0 = 0; pResult->QWords.qw1 = 0; pResult->QWords.qw2 = pValue->QWords.qw0 << cBits; pResult->QWords.qw3 = pValue->QWords.qw0 >> (64 - cBits); pResult->QWords.qw3 |= pValue->QWords.qw1 << cBits; } else { cBits -= 192; pResult->QWords.qw0 = 0; pResult->QWords.qw1 = 0; pResult->QWords.qw2 = 0; pResult->QWords.qw3 = pValue->QWords.qw0 << cBits; } } return pResult; } /** * Shifts a 256-bit unsigned integer value @a cBits to the right. * * @returns pResult * @param pResult The result variable. * @param pValue The value to shift. * @param cBits The number of bits to shift it. This is masked * by 255 before shifting. */ DECLINLINE(PRTUINT256U) RTUInt256ShiftRight(PRTUINT256U pResult, PCRTUINT256U pValue, unsigned cBits) { /* This is a bit bulky & impractical since we cannot access the data using an array because it is organized according to host endianness. Sigh. */ cBits &= 255; if (!(cBits & 0x3f)) { if (cBits == 0) *pResult = *pValue; else { if (cBits == 64) { pResult->QWords.qw0 = pValue->QWords.qw1; pResult->QWords.qw1 = pValue->QWords.qw2; pResult->QWords.qw2 = pValue->QWords.qw3; } else { if (cBits == 128) { pResult->QWords.qw0 = pValue->QWords.qw2; pResult->QWords.qw1 = pValue->QWords.qw3; } else { pResult->QWords.qw0 = pValue->QWords.qw3; pResult->QWords.qw1 = 0; } pResult->QWords.qw2 = 0; } pResult->QWords.qw3 = 0; } } else if (cBits < 128) { if (cBits < 64) { pResult->QWords.qw0 = pValue->QWords.qw0 >> cBits; pResult->QWords.qw0 |= pValue->QWords.qw1 << (64 - cBits); pResult->QWords.qw1 = pValue->QWords.qw1 >> cBits; pResult->QWords.qw1 |= pValue->QWords.qw2 << (64 - cBits); pResult->QWords.qw2 = pValue->QWords.qw2 >> cBits; pResult->QWords.qw2 |= pValue->QWords.qw3 << (64 - cBits); pResult->QWords.qw3 = pValue->QWords.qw3 >> cBits; } else { cBits -= 64; pResult->QWords.qw0 = pValue->QWords.qw1 >> cBits; pResult->QWords.qw0 |= pValue->QWords.qw2 << (64 - cBits); pResult->QWords.qw1 = pValue->QWords.qw2 >> cBits; pResult->QWords.qw1 |= pValue->QWords.qw3 << (64 - cBits); pResult->QWords.qw2 = pValue->QWords.qw3 >> cBits; pResult->QWords.qw3 = 0; } } else { if (cBits < 192) { cBits -= 128; pResult->QWords.qw0 = pValue->QWords.qw2 >> cBits; pResult->QWords.qw0 |= pValue->QWords.qw3 << (64 - cBits); pResult->QWords.qw1 = pValue->QWords.qw3 >> cBits; pResult->QWords.qw2 = 0; pResult->QWords.qw3 = 0; } else { cBits -= 192; pResult->QWords.qw0 = pValue->QWords.qw3 >> cBits; pResult->QWords.qw1 = 0; pResult->QWords.qw2 = 0; pResult->QWords.qw3 = 0; } } return pResult; } /** * Boolean not (result 0 or 1). * * @returns pResult. * @param pResult The result variable. * @param pValue The value. */ DECLINLINE(PRTUINT256U) RTUInt256BooleanNot(PRTUINT256U pResult, PCRTUINT256U pValue) { pResult->QWords.qw0 = RTUInt256IsZero(pValue); pResult->QWords.qw1 = 0; pResult->QWords.qw2 = 0; pResult->QWords.qw3 = 0; return pResult; } /** * Bitwise not (flips each bit of the 256 bits). * * @returns pResult. * @param pResult The result variable. * @param pValue The value. */ DECLINLINE(PRTUINT256U) RTUInt256BitwiseNot(PRTUINT256U pResult, PCRTUINT256U pValue) { pResult->QWords.qw0 = ~pValue->QWords.qw0; pResult->QWords.qw1 = ~pValue->QWords.qw1; pResult->QWords.qw2 = ~pValue->QWords.qw2; pResult->QWords.qw3 = ~pValue->QWords.qw3; return pResult; } /** * Assigns one 256-bit unsigned integer value to another. * * @returns pResult * @param pResult The result variable. * @param pValue The value to assign. */ DECLINLINE(PRTUINT256U) RTUInt256Assign(PRTUINT256U pResult, PCRTUINT256U pValue) { pResult->QWords.qw0 = pValue->QWords.qw0; pResult->QWords.qw1 = pValue->QWords.qw1; pResult->QWords.qw2 = pValue->QWords.qw2; pResult->QWords.qw3 = pValue->QWords.qw3; return pResult; } /** * Assigns a boolean value to 256-bit unsigned integer. * * @returns pValueResult * @param pValueResult The result variable. * @param fValue The boolean value. */ DECLINLINE(PRTUINT256U) RTUInt256AssignBoolean(PRTUINT256U pValueResult, bool fValue) { pValueResult->QWords.qw0 = fValue; pValueResult->QWords.qw1 = 0; pValueResult->QWords.qw2 = 0; pValueResult->QWords.qw3 = 0; return pValueResult; } /** * Assigns a 8-bit unsigned integer value to 256-bit unsigned integer. * * @returns pValueResult * @param pValueResult The result variable. * @param u8Value The 8-bit unsigned integer value. */ DECLINLINE(PRTUINT256U) RTUInt256AssignU8(PRTUINT256U pValueResult, uint8_t u8Value) { pValueResult->QWords.qw0 = u8Value; pValueResult->QWords.qw1 = 0; pValueResult->QWords.qw2 = 0; pValueResult->QWords.qw3 = 0; return pValueResult; } /** * Assigns a 16-bit unsigned integer value to 256-bit unsigned integer. * * @returns pValueResult * @param pValueResult The result variable. * @param u16Value The 16-bit unsigned integer value. */ DECLINLINE(PRTUINT256U) RTUInt256AssignU16(PRTUINT256U pValueResult, uint16_t u16Value) { pValueResult->QWords.qw0 = u16Value; pValueResult->QWords.qw1 = 0; pValueResult->QWords.qw2 = 0; pValueResult->QWords.qw3 = 0; return pValueResult; } /** * Assigns a 32-bit unsigned integer value to 256-bit unsigned integer. * * @returns pValueResult * @param pValueResult The result variable. * @param u32Value The 32-bit unsigned integer value. */ DECLINLINE(PRTUINT256U) RTUInt256AssignU32(PRTUINT256U pValueResult, uint32_t u32Value) { pValueResult->QWords.qw0 = u32Value; pValueResult->QWords.qw1 = 0; pValueResult->QWords.qw2 = 0; pValueResult->QWords.qw3 = 0; return pValueResult; } /** * Assigns a 64-bit unsigned integer value to 256-bit unsigned integer. * * @returns pValueResult * @param pValueResult The result variable. * @param u64Value The 64-bit unsigned integer value. */ DECLINLINE(PRTUINT256U) RTUInt256AssignU64(PRTUINT256U pValueResult, uint64_t u64Value) { pValueResult->QWords.qw0 = u64Value; pValueResult->QWords.qw1 = 0; pValueResult->QWords.qw2 = 0; pValueResult->QWords.qw3 = 0; return pValueResult; } /** * Adds two 256-bit unsigned integer values, storing the result in the first. * * @returns pValue1Result. * @param pValue1Result The first value and result. * @param pValue2 The second value. */ DECLINLINE(PRTUINT256U) RTUInt256AssignAdd(PRTUINT256U pValue1Result, PCRTUINT256U pValue2) { RTUINT256U const uTmpValue1 = *pValue1Result; /* lazy bird */ return RTUInt256Add(pValue1Result, &uTmpValue1, pValue2); } /** * Adds a 64-bit unsigned integer value to a 256-bit unsigned integer values, * storing the result in the 256-bit one. * * @returns pValue1Result. * @param pValue1Result The first value and result. * @param uValue2 The second value, 64-bit. */ DECLINLINE(PRTUINT256U) RTUInt256AssignAddU64(PRTUINT256U pValue1Result, uint64_t uValue2) { RTUINT256U const uTmpValue1 = *pValue1Result; /* lazy bird */ return RTUInt256AddU64(pValue1Result, &uTmpValue1, uValue2); } /** * Subtracts two 256-bit unsigned integer values, storing the result in the * first. * * @returns pValue1Result. * @param pValue1Result The minuend value and result. * @param pValue2 The subtrahend value. */ DECLINLINE(PRTUINT256U) RTUInt256AssignSub(PRTUINT256U pValue1Result, PCRTUINT256U pValue2) { RTUINT256U const uTmpValue1 = *pValue1Result; /* lazy bird */ return RTUInt256Sub(pValue1Result, &uTmpValue1, pValue2); } #if 0 /** * Negates a 256 number, storing the result in the input. * * @returns pValueResult. * @param pValueResult The value to negate. */ DECLINLINE(PRTUINT256U) RTUInt256AssignNeg(PRTUINT256U pValueResult) { /* result = 0 - value */ if (pValueResult->s.Lo != 0) { pValueResult->s.Lo = UINT64_C(0) - pValueResult->s.Lo; pValueResult->s.Hi = UINT64_MAX - pValueResult->s.Hi; } else pValueResult->s.Hi = UINT64_C(0) - pValueResult->s.Hi; return pValueResult; } #endif /** * Multiplies two 256-bit unsigned integer values, storing the result in the * first. * * @returns pValue1Result. * @param pValue1Result The first value and result. * @param pValue2 The second value. */ DECLINLINE(PRTUINT256U) RTUInt256AssignMul(PRTUINT256U pValue1Result, PCRTUINT256U pValue2) { RTUINT256U Result; RTUInt256Mul(&Result, pValue1Result, pValue2); *pValue1Result = Result; return pValue1Result; } /** * Divides a 256-bit unsigned integer value by another, storing the result in * the first. * * @returns pValue1Result. * @param pValue1Result The dividend value and result. * @param pValue2 The divisor value. */ DECLINLINE(PRTUINT256U) RTUInt256AssignDiv(PRTUINT256U pValue1Result, PCRTUINT256U pValue2) { RTUINT256U Result; RTUINT256U Ignored; RTUInt256DivRem(&Result, &Ignored, pValue1Result, pValue2); *pValue1Result = Result; return pValue1Result; } /** * Divides a 256-bit unsigned integer value by another, storing the remainder in * the first. * * @returns pValue1Result. * @param pValue1Result The dividend value and result (remainder). * @param pValue2 The divisor value. */ DECLINLINE(PRTUINT256U) RTUInt256AssignMod(PRTUINT256U pValue1Result, PCRTUINT256U pValue2) { RTUINT256U Ignored; RTUINT256U Result; RTUInt256DivRem(&Ignored, &Result, pValue1Result, pValue2); *pValue1Result = Result; return pValue1Result; } /** * Performs a bitwise AND of two 256-bit unsigned integer values and assigned * the result to the first one. * * @returns pValue1Result. * @param pValue1Result The first value and result. * @param pValue2 The second value. */ DECLINLINE(PRTUINT256U) RTUInt256AssignAnd(PRTUINT256U pValue1Result, PCRTUINT256U pValue2) { pValue1Result->QWords.qw0 &= pValue2->QWords.qw0; pValue1Result->QWords.qw1 &= pValue2->QWords.qw1; pValue1Result->QWords.qw2 &= pValue2->QWords.qw2; pValue1Result->QWords.qw3 &= pValue2->QWords.qw3; return pValue1Result; } #if 0 /** * Performs a bitwise AND of a 256-bit unsigned integer value and a mask made * up of the first N bits, assigning the result to the the 256-bit value. * * @returns pValueResult. * @param pValueResult The value and result. * @param cBits The number of bits to AND (counting from the first * bit). */ DECLINLINE(PRTUINT256U) RTUInt256AssignAndNFirstBits(PRTUINT256U pValueResult, unsigned cBits) { if (cBits <= 64) { if (cBits != 64) pValueResult->s.Lo &= (RT_BIT_64(cBits) - 1); pValueResult->s.Hi = 0; } else if (cBits < 256) pValueResult->s.Hi &= (RT_BIT_64(cBits - 64) - 1); /** @todo \#if ARCH_BITS >= 64 */ return pValueResult; } #endif /** * Performs a bitwise OR of two 256-bit unsigned integer values and assigned * the result to the first one. * * @returns pValue1Result. * @param pValue1Result The first value and result. * @param pValue2 The second value. */ DECLINLINE(PRTUINT256U) RTUInt256AssignOr(PRTUINT256U pValue1Result, PCRTUINT256U pValue2) { pValue1Result->QWords.qw0 |= pValue2->QWords.qw0; pValue1Result->QWords.qw1 |= pValue2->QWords.qw1; pValue1Result->QWords.qw2 |= pValue2->QWords.qw2; pValue1Result->QWords.qw3 |= pValue2->QWords.qw3; return pValue1Result; } DECLINLINE(PRTUINT256U) RTUInt256BitSet(PRTUINT256U pValueResult, unsigned iBit); /** * ORs in a bit and assign the result to the input value. * * @returns pValue1Result. * @param pValue1Result The first value and result. * @param iBit The bit to set (0 based). */ DECLINLINE(PRTUINT256U) RTUInt256AssignOrBit(PRTUINT256U pValue1Result, uint32_t iBit) { return RTUInt256BitSet(pValue1Result, (unsigned)iBit); } /** * Performs a bitwise XOR of two 256-bit unsigned integer values and assigned * the result to the first one. * * @returns pValue1Result. * @param pValue1Result The first value and result. * @param pValue2 The second value. */ DECLINLINE(PRTUINT256U) RTUInt256AssignXor(PRTUINT256U pValue1Result, PCRTUINT256U pValue2) { pValue1Result->QWords.qw0 ^= pValue2->QWords.qw0; pValue1Result->QWords.qw1 ^= pValue2->QWords.qw1; pValue1Result->QWords.qw2 ^= pValue2->QWords.qw2; pValue1Result->QWords.qw3 ^= pValue2->QWords.qw3; return pValue1Result; } /** * Performs a bitwise left shift on a 256-bit unsigned integer value, assigning * the result to it. * * @returns pValueResult. * @param pValueResult The first value and result. * @param cBits The number of bits to shift - signed. Negative * values are translated to right shifts. If the * absolute value is 256 or higher, the value is set to * zero. * * @note This works differently from RTUInt256ShiftLeft and * RTUInt256ShiftRight in that the shift count is signed and not masked * by 255. */ DECLINLINE(PRTUINT256U) RTUInt256AssignShiftLeft(PRTUINT256U pValueResult, int cBits) { if (cBits == 0) return pValueResult; if (cBits > 0) { /* (left shift) */ if (cBits < 256) { RTUINT256U const InVal = *pValueResult; return RTUInt256ShiftLeft(pValueResult, &InVal, cBits); } } else if (cBits > -256) { /* (right shift) */ cBits = -cBits; RTUINT256U const InVal = *pValueResult; return RTUInt256ShiftRight(pValueResult, &InVal, cBits); } return RTUInt256SetZero(pValueResult); } /** * Performs a bitwise left shift on a 256-bit unsigned integer value, assigning * the result to it. * * @returns pValueResult. * @param pValueResult The first value and result. * @param cBits The number of bits to shift - signed. Negative * values are translated to left shifts. If the * absolute value is 256 or higher, the value is set to * zero. * * @note This works differently from RTUInt256ShiftRight and * RTUInt256ShiftLeft in that the shift count is signed and not masked * by 255. */ DECLINLINE(PRTUINT256U) RTUInt256AssignShiftRight(PRTUINT256U pValueResult, int cBits) { if (cBits == 0) return pValueResult; if (cBits > 0) { /* (right shift) */ if (cBits < 256) { RTUINT256U const InVal = *pValueResult; return RTUInt256ShiftRight(pValueResult, &InVal, cBits); } } else if (cBits > -256) { /* (left shift) */ cBits = -cBits; RTUINT256U const InVal = *pValueResult; return RTUInt256ShiftLeft(pValueResult, &InVal, cBits); } return RTUInt256SetZero(pValueResult); } /** * Performs a bitwise NOT on a 256-bit unsigned integer value, assigning the * result to it. * * @returns pValueResult * @param pValueResult The value and result. */ DECLINLINE(PRTUINT256U) RTUInt256AssignBitwiseNot(PRTUINT256U pValueResult) { pValueResult->QWords.qw0 = ~pValueResult->QWords.qw0; pValueResult->QWords.qw1 = ~pValueResult->QWords.qw1; pValueResult->QWords.qw2 = ~pValueResult->QWords.qw2; pValueResult->QWords.qw3 = ~pValueResult->QWords.qw3; return pValueResult; } /** * Performs a boolean NOT on a 256-bit unsigned integer value, assigning the * result to it. * * @returns pValueResult * @param pValueResult The value and result. */ DECLINLINE(PRTUINT256U) RTUInt256AssignBooleanNot(PRTUINT256U pValueResult) { return RTUInt256AssignBoolean(pValueResult, RTUInt256IsZero(pValueResult)); } /** * Compares two 256-bit unsigned integer values. * * @retval 0 if equal. * @retval -1 if the first value is smaller than the second. * @retval 1 if the first value is larger than the second. * * @param pValue1 The first value. * @param pValue2 The second value. */ DECLINLINE(int) RTUInt256Compare(PCRTUINT256U pValue1, PCRTUINT256U pValue2) { if (pValue1->QWords.qw3 != pValue2->QWords.qw3) return pValue1->QWords.qw3 > pValue2->QWords.qw3 ? 1 : -1; if (pValue1->QWords.qw2 != pValue2->QWords.qw2) return pValue1->QWords.qw2 > pValue2->QWords.qw2 ? 1 : -1; if (pValue1->QWords.qw1 != pValue2->QWords.qw1) return pValue1->QWords.qw1 > pValue2->QWords.qw1 ? 1 : -1; if (pValue1->QWords.qw0 != pValue2->QWords.qw0) return pValue1->QWords.qw3 > pValue2->QWords.qw3 ? 1 : -1; return 0; } /** * Tests if a 256-bit unsigned integer value is smaller than another. * * @returns true if the first value is smaller, false if not. * @param pValue1 The first value. * @param pValue2 The second value. */ DECLINLINE(bool) RTUInt256IsSmaller(PCRTUINT256U pValue1, PCRTUINT256U pValue2) { return pValue1->QWords.qw3 < pValue2->QWords.qw3 || ( pValue1->QWords.qw3 == pValue2->QWords.qw3 && ( pValue1->QWords.qw2 < pValue2->QWords.qw2 || ( pValue1->QWords.qw2 == pValue2->QWords.qw2 && ( pValue1->QWords.qw1 < pValue2->QWords.qw1 || ( pValue1->QWords.qw1 == pValue2->QWords.qw1 && pValue1->QWords.qw0 < pValue2->QWords.qw0))))); } /** * Tests if a 256-bit unsigned integer value is larger than another. * * @returns true if the first value is larger, false if not. * @param pValue1 The first value. * @param pValue2 The second value. */ DECLINLINE(bool) RTUInt256IsLarger(PCRTUINT256U pValue1, PCRTUINT256U pValue2) { return pValue1->QWords.qw3 > pValue2->QWords.qw3 || ( pValue1->QWords.qw3 == pValue2->QWords.qw3 && ( pValue1->QWords.qw2 > pValue2->QWords.qw2 || ( pValue1->QWords.qw2 == pValue2->QWords.qw2 && ( pValue1->QWords.qw1 > pValue2->QWords.qw1 || ( pValue1->QWords.qw1 == pValue2->QWords.qw1 && pValue1->QWords.qw0 > pValue2->QWords.qw0))))); } /** * Tests if a 256-bit unsigned integer value is larger or equal than another. * * @returns true if the first value is larger or equal, false if not. * @param pValue1 The first value. * @param pValue2 The second value. */ DECLINLINE(bool) RTUInt256IsLargerOrEqual(PCRTUINT256U pValue1, PCRTUINT256U pValue2) { return pValue1->QWords.qw3 > pValue2->QWords.qw3 || ( pValue1->QWords.qw3 == pValue2->QWords.qw3 && ( pValue1->QWords.qw2 > pValue2->QWords.qw2 || ( pValue1->QWords.qw2 == pValue2->QWords.qw2 && ( pValue1->QWords.qw1 > pValue2->QWords.qw1 || ( pValue1->QWords.qw1 == pValue2->QWords.qw1 && pValue1->QWords.qw0 >= pValue2->DWords.dw0))))); } /** * Tests if two 256-bit unsigned integer values not equal. * * @returns true if equal, false if not equal. * @param pValue1 The first value. * @param pValue2 The second value. */ DECLINLINE(bool) RTUInt256IsEqual(PCRTUINT256U pValue1, PCRTUINT256U pValue2) { return pValue1->QWords.qw0 == pValue2->QWords.qw0 && pValue1->QWords.qw1 == pValue2->QWords.qw1 && pValue1->QWords.qw2 == pValue2->QWords.qw2 && pValue1->QWords.qw3 == pValue2->QWords.qw3; } /** * Tests if two 256-bit unsigned integer values are not equal. * * @returns true if not equal, false if equal. * @param pValue1 The first value. * @param pValue2 The second value. */ DECLINLINE(bool) RTUInt256IsNotEqual(PCRTUINT256U pValue1, PCRTUINT256U pValue2) { return !RTUInt256IsEqual(pValue1, pValue2); } /** * Sets a bit in a 256-bit unsigned integer type. * * @returns pValueResult. * @param pValueResult The input and output value. * @param iBit The bit to set. */ DECLINLINE(PRTUINT256U) RTUInt256BitSet(PRTUINT256U pValueResult, unsigned iBit) { if (iBit < 256) { unsigned idxQWord = iBit >> 6; #ifdef RT_BIG_ENDIAN idxQWord = RT_ELEMENTS(pValueResult->au64) - idxQWord; #endif iBit &= 0x3f; pValueResult->au64[idxQWord] |= RT_BIT_64(iBit); } return pValueResult; } /** * Sets a bit in a 256-bit unsigned integer type. * * @returns pValueResult. * @param pValueResult The input and output value. * @param iBit The bit to set. */ DECLINLINE(PRTUINT256U) RTUInt256BitClear(PRTUINT256U pValueResult, unsigned iBit) { if (iBit < 256) { unsigned idxQWord = iBit >> 6; #ifdef RT_BIG_ENDIAN idxQWord = RT_ELEMENTS(pValueResult->au64) - idxQWord; #endif iBit &= 0x3f; pValueResult->au64[idxQWord] &= ~RT_BIT_64(iBit); } return pValueResult; } /** * Tests if a bit in a 256-bit unsigned integer value is set. * * @returns pValueResult. * @param pValueResult The input and output value. * @param iBit The bit to test. */ DECLINLINE(bool) RTUInt256BitTest(PRTUINT256U pValueResult, unsigned iBit) { bool fRc; if (iBit < 256) { unsigned idxQWord = iBit >> 6; #ifdef RT_BIG_ENDIAN idxQWord = RT_ELEMENTS(pValueResult->au64) - idxQWord; #endif iBit &= 0x3f; fRc = RT_BOOL(pValueResult->au64[idxQWord] & RT_BIT_64(iBit)); } else fRc = false; return fRc; } /** * Set a range of bits a 256-bit unsigned integer value. * * @returns pValueResult. * @param pValueResult The input and output value. * @param iFirstBit The first bit to test. * @param cBits The number of bits to set. */ DECLINLINE(PRTUINT256U) RTUInt256BitSetRange(PRTUINT256U pValueResult, unsigned iFirstBit, unsigned cBits) { /* bounds check & fix. */ if (iFirstBit < 256) { if (iFirstBit + cBits > 256) cBits = 256 - iFirstBit; /* Work the au64 array: */ #ifdef RT_BIG_ENDIAN int idxQWord = RT_ELEMENTS(pValueResult->au64) - (iFirstBit >> 6); int const idxInc = -1; #else int idxQWord = iFirstBit >> 6; int const idxInc = 1; #endif while (cBits > 0) { unsigned iQWordFirstBit = iFirstBit & 0x3f; unsigned cQWordBits = cBits + iQWordFirstBit >= 64 ? 64 - iQWordFirstBit : cBits; pValueResult->au64[idxQWord] |= cQWordBits < 64 ? (RT_BIT_64(cQWordBits) - 1) << iQWordFirstBit : UINT64_MAX; idxQWord += idxInc; iFirstBit += cQWordBits; cBits -= cQWordBits; } } return pValueResult; } /** * Test if all the bits of a 256-bit unsigned integer value are set. * * @returns true if they are, false if they aren't. * @param pValue The input and output value. */ DECLINLINE(bool) RTUInt256BitAreAllSet(PRTUINT256U pValue) { return pValue->QWords.qw0 == UINT64_MAX && pValue->QWords.qw1 == UINT64_MAX && pValue->QWords.qw2 == UINT64_MAX && pValue->QWords.qw3 == UINT64_MAX; } /** * Test if all the bits of a 256-bit unsigned integer value are clear. * * @returns true if they are, false if they aren't. * @param pValue The input and output value. */ DECLINLINE(bool) RTUInt256BitAreAllClear(PRTUINT256U pValue) { return RTUInt256IsZero(pValue); } /** * Number of significant bits in the value. * * This is the same a ASMBitLastSetU64 and ASMBitLastSetU32. * * @returns 0 if zero, 1-base index of the last bit set. * @param pValue The value to examine. */ DECLINLINE(uint32_t) RTUInt256BitCount(PCRTUINT256U pValue) { uint64_t u64; uint32_t cBits; if ((u64 = pValue->QWords.qw3) != 0) cBits = 192; else if ((u64 = pValue->QWords.qw2) != 0) cBits = 128; else if ((u64 = pValue->QWords.qw1) != 0) cBits = 64; else { u64 = pValue->QWords.qw0; cBits = 0; } return cBits + ASMBitLastSetU64(u64); } /** @} */ RT_C_DECLS_END #endif /* !IPRT_INCLUDED_uint256_h */