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author | Mattes D <github@xoft.cz> | 2013-11-27 09:23:17 +0100 |
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committer | Mattes D <github@xoft.cz> | 2013-11-27 09:23:17 +0100 |
commit | 49760db89d94ede5d123d927141a6cd60dbaaf07 (patch) | |
tree | 6c6cf99e4cf3128311a93cd187947b502f3732a0 /lib/cryptopp/vmac.cpp | |
parent | cWorld::SpawnExperienceOrb() now returns the entity ID of the spawned orb. (diff) | |
parent | Fixed VC2008 compilation, normalized include paths. (diff) | |
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Diffstat (limited to 'lib/cryptopp/vmac.cpp')
-rw-r--r-- | lib/cryptopp/vmac.cpp | 832 |
1 files changed, 832 insertions, 0 deletions
diff --git a/lib/cryptopp/vmac.cpp b/lib/cryptopp/vmac.cpp new file mode 100644 index 000000000..6b490f904 --- /dev/null +++ b/lib/cryptopp/vmac.cpp @@ -0,0 +1,832 @@ +// vmac.cpp - written and placed in the public domain by Wei Dai +// based on Ted Krovetz's public domain vmac.c and draft-krovetz-vmac-01.txt + +#include "pch.h" +#include "vmac.h" +#include "argnames.h" +#include "cpu.h" + +NAMESPACE_BEGIN(CryptoPP) + +#if defined(_MSC_VER) && !CRYPTOPP_BOOL_SLOW_WORD64 +#include <intrin.h> +#endif + +#define VMAC_BOOL_WORD128 (defined(CRYPTOPP_WORD128_AVAILABLE) && !defined(CRYPTOPP_X64_ASM_AVAILABLE)) +#ifdef __BORLANDC__ +#define const // Turbo C++ 2006 workaround +#endif +static const word64 p64 = W64LIT(0xfffffffffffffeff); /* 2^64 - 257 prime */ +static const word64 m62 = W64LIT(0x3fffffffffffffff); /* 62-bit mask */ +static const word64 m63 = W64LIT(0x7fffffffffffffff); /* 63-bit mask */ +static const word64 m64 = W64LIT(0xffffffffffffffff); /* 64-bit mask */ +static const word64 mpoly = W64LIT(0x1fffffff1fffffff); /* Poly key mask */ +#ifdef __BORLANDC__ +#undef const +#endif +#if VMAC_BOOL_WORD128 +#ifdef __powerpc__ +// workaround GCC Bug 31690: ICE with const __uint128_t and C++ front-end +#define m126 ((word128(m62)<<64)|m64) +#else +static const word128 m126 = (word128(m62)<<64)|m64; /* 126-bit mask */ +#endif +#endif + +void VMAC_Base::UncheckedSetKey(const byte *userKey, unsigned int keylength, const NameValuePairs ¶ms) +{ + int digestLength = params.GetIntValueWithDefault(Name::DigestSize(), DefaultDigestSize()); + if (digestLength != 8 && digestLength != 16) + throw InvalidArgument("VMAC: DigestSize must be 8 or 16"); + m_is128 = digestLength == 16; + + m_L1KeyLength = params.GetIntValueWithDefault(Name::L1KeyLength(), 128); + if (m_L1KeyLength <= 0 || m_L1KeyLength % 128 != 0) + throw InvalidArgument("VMAC: L1KeyLength must be a positive multiple of 128"); + + AllocateBlocks(); + + BlockCipher &cipher = AccessCipher(); + cipher.SetKey(userKey, keylength, params); + unsigned int blockSize = cipher.BlockSize(); + unsigned int blockSizeInWords = blockSize / sizeof(word64); + SecBlock<word64> out(blockSizeInWords); + SecByteBlock in; + in.CleanNew(blockSize); + size_t i; + + /* Fill nh key */ + in[0] = 0x80; + cipher.AdvancedProcessBlocks(in, NULL, (byte *)m_nhKey(), m_nhKeySize()*sizeof(word64), cipher.BT_InBlockIsCounter); + ConditionalByteReverse<word64>(BIG_ENDIAN_ORDER, m_nhKey(), m_nhKey(), m_nhKeySize()*sizeof(word64)); + + /* Fill poly key */ + in[0] = 0xC0; + in[15] = 0; + for (i = 0; i <= (size_t)m_is128; i++) + { + cipher.ProcessBlock(in, out.BytePtr()); + m_polyState()[i*4+2] = GetWord<word64>(true, BIG_ENDIAN_ORDER, out.BytePtr()) & mpoly; + m_polyState()[i*4+3] = GetWord<word64>(true, BIG_ENDIAN_ORDER, out.BytePtr()+8) & mpoly; + in[15]++; + } + + /* Fill ip key */ + in[0] = 0xE0; + in[15] = 0; + word64 *l3Key = m_l3Key(); + for (i = 0; i <= (size_t)m_is128; i++) + do + { + cipher.ProcessBlock(in, out.BytePtr()); + l3Key[i*2+0] = GetWord<word64>(true, BIG_ENDIAN_ORDER, out.BytePtr()); + l3Key[i*2+1] = GetWord<word64>(true, BIG_ENDIAN_ORDER, out.BytePtr()+8); + in[15]++; + } while ((l3Key[i*2+0] >= p64) || (l3Key[i*2+1] >= p64)); + + m_padCached = false; + size_t nonceLength; + const byte *nonce = GetIVAndThrowIfInvalid(params, nonceLength); + Resynchronize(nonce, (int)nonceLength); +} + +void VMAC_Base::GetNextIV(RandomNumberGenerator &rng, byte *IV) +{ + SimpleKeyingInterface::GetNextIV(rng, IV); + IV[0] &= 0x7f; +} + +void VMAC_Base::Resynchronize(const byte *nonce, int len) +{ + size_t length = ThrowIfInvalidIVLength(len); + size_t s = IVSize(); + byte *storedNonce = m_nonce(); + + if (m_is128) + { + memset(storedNonce, 0, s-length); + memcpy(storedNonce+s-length, nonce, length); + AccessCipher().ProcessBlock(storedNonce, m_pad()); + } + else + { + if (m_padCached && (storedNonce[s-1] | 1) == (nonce[length-1] | 1)) + { + m_padCached = VerifyBufsEqual(storedNonce+s-length, nonce, length-1); + for (size_t i=0; m_padCached && i<s-length; i++) + m_padCached = (storedNonce[i] == 0); + } + if (!m_padCached) + { + memset(storedNonce, 0, s-length); + memcpy(storedNonce+s-length, nonce, length-1); + storedNonce[s-1] = nonce[length-1] & 0xfe; + AccessCipher().ProcessBlock(storedNonce, m_pad()); + m_padCached = true; + } + storedNonce[s-1] = nonce[length-1]; + } + m_isFirstBlock = true; + Restart(); +} + +void VMAC_Base::HashEndianCorrectedBlock(const word64 *data) +{ + assert(false); + throw 0; +} + +#if CRYPTOPP_BOOL_SSE2_ASM_AVAILABLE && CRYPTOPP_BOOL_X86 +#pragma warning(disable: 4731) // frame pointer register 'ebp' modified by inline assembly code +void +#ifdef __GNUC__ +__attribute__ ((noinline)) // Intel Compiler 9.1 workaround +#endif +VMAC_Base::VHASH_Update_SSE2(const word64 *data, size_t blocksRemainingInWord64, int tagPart) +{ + const word64 *nhK = m_nhKey(); + word64 *polyS = m_polyState(); + word32 L1KeyLength = m_L1KeyLength; + +#ifdef __GNUC__ + word32 temp; + __asm__ __volatile__ + ( + AS2( mov %%ebx, %0) + AS2( mov %1, %%ebx) + ".intel_syntax noprefix;" +#else + #if _MSC_VER < 1300 || defined(__INTEL_COMPILER) + char isFirstBlock = m_isFirstBlock; + AS2( mov ebx, [L1KeyLength]) + AS2( mov dl, [isFirstBlock]) + #else + AS2( mov ecx, this) + AS2( mov ebx, [ecx+m_L1KeyLength]) + AS2( mov dl, [ecx+m_isFirstBlock]) + #endif + AS2( mov eax, tagPart) + AS2( shl eax, 4) + AS2( mov edi, nhK) + AS2( add edi, eax) + AS2( add eax, eax) + AS2( add eax, polyS) + + AS2( mov esi, data) + AS2( mov ecx, blocksRemainingInWord64) +#endif + + AS2( shr ebx, 3) + AS1( push ebp) + AS2( sub esp, 12) + ASL(4) + AS2( mov ebp, ebx) + AS2( cmp ecx, ebx) + AS2( cmovl ebp, ecx) + AS2( sub ecx, ebp) + AS2( lea ebp, [edi+8*ebp]) // end of nhK + AS2( movq mm6, [esi]) + AS2( paddq mm6, [edi]) + AS2( movq mm5, [esi+8]) + AS2( paddq mm5, [edi+8]) + AS2( add esi, 16) + AS2( add edi, 16) + AS2( movq mm4, mm6) + ASS( pshufw mm2, mm6, 1, 0, 3, 2) + AS2( pmuludq mm6, mm5) + ASS( pshufw mm3, mm5, 1, 0, 3, 2) + AS2( pmuludq mm5, mm2) + AS2( pmuludq mm2, mm3) + AS2( pmuludq mm3, mm4) + AS2( pxor mm7, mm7) + AS2( movd [esp], mm6) + AS2( psrlq mm6, 32) + AS2( movd [esp+4], mm5) + AS2( psrlq mm5, 32) + AS2( cmp edi, ebp) + ASJ( je, 1, f) + ASL(0) + AS2( movq mm0, [esi]) + AS2( paddq mm0, [edi]) + AS2( movq mm1, [esi+8]) + AS2( paddq mm1, [edi+8]) + AS2( add esi, 16) + AS2( add edi, 16) + AS2( movq mm4, mm0) + AS2( paddq mm5, mm2) + ASS( pshufw mm2, mm0, 1, 0, 3, 2) + AS2( pmuludq mm0, mm1) + AS2( movd [esp+8], mm3) + AS2( psrlq mm3, 32) + AS2( paddq mm5, mm3) + ASS( pshufw mm3, mm1, 1, 0, 3, 2) + AS2( pmuludq mm1, mm2) + AS2( pmuludq mm2, mm3) + AS2( pmuludq mm3, mm4) + AS2( movd mm4, [esp]) + AS2( paddq mm7, mm4) + AS2( movd mm4, [esp+4]) + AS2( paddq mm6, mm4) + AS2( movd mm4, [esp+8]) + AS2( paddq mm6, mm4) + AS2( movd [esp], mm0) + AS2( psrlq mm0, 32) + AS2( paddq mm6, mm0) + AS2( movd [esp+4], mm1) + AS2( psrlq mm1, 32) + AS2( paddq mm5, mm1) + AS2( cmp edi, ebp) + ASJ( jne, 0, b) + ASL(1) + AS2( paddq mm5, mm2) + AS2( movd [esp+8], mm3) + AS2( psrlq mm3, 32) + AS2( paddq mm5, mm3) + AS2( movd mm4, [esp]) + AS2( paddq mm7, mm4) + AS2( movd mm4, [esp+4]) + AS2( paddq mm6, mm4) + AS2( movd mm4, [esp+8]) + AS2( paddq mm6, mm4) + AS2( lea ebp, [8*ebx]) + AS2( sub edi, ebp) // reset edi to start of nhK + + AS2( movd [esp], mm7) + AS2( psrlq mm7, 32) + AS2( paddq mm6, mm7) + AS2( movd [esp+4], mm6) + AS2( psrlq mm6, 32) + AS2( paddq mm5, mm6) + AS2( psllq mm5, 2) + AS2( psrlq mm5, 2) + +#define a0 [eax+2*4] +#define a1 [eax+3*4] +#define a2 [eax+0*4] +#define a3 [eax+1*4] +#define k0 [eax+2*8+2*4] +#define k1 [eax+2*8+3*4] +#define k2 [eax+2*8+0*4] +#define k3 [eax+2*8+1*4] + AS2( test dl, dl) + ASJ( jz, 2, f) + AS2( movd mm1, k0) + AS2( movd mm0, [esp]) + AS2( paddq mm0, mm1) + AS2( movd a0, mm0) + AS2( psrlq mm0, 32) + AS2( movd mm1, k1) + AS2( movd mm2, [esp+4]) + AS2( paddq mm1, mm2) + AS2( paddq mm0, mm1) + AS2( movd a1, mm0) + AS2( psrlq mm0, 32) + AS2( paddq mm5, k2) + AS2( paddq mm0, mm5) + AS2( movq a2, mm0) + AS2( xor edx, edx) + ASJ( jmp, 3, f) + ASL(2) + AS2( movd mm0, a3) + AS2( movq mm4, mm0) + AS2( pmuludq mm0, k3) // a3*k3 + AS2( movd mm1, a0) + AS2( pmuludq mm1, k2) // a0*k2 + AS2( movd mm2, a1) + AS2( movd mm6, k1) + AS2( pmuludq mm2, mm6) // a1*k1 + AS2( movd mm3, a2) + AS2( psllq mm0, 1) + AS2( paddq mm0, mm5) + AS2( movq mm5, mm3) + AS2( movd mm7, k0) + AS2( pmuludq mm3, mm7) // a2*k0 + AS2( pmuludq mm4, mm7) // a3*k0 + AS2( pmuludq mm5, mm6) // a2*k1 + AS2( paddq mm0, mm1) + AS2( movd mm1, a1) + AS2( paddq mm4, mm5) + AS2( movq mm5, mm1) + AS2( pmuludq mm1, k2) // a1*k2 + AS2( paddq mm0, mm2) + AS2( movd mm2, a0) + AS2( paddq mm0, mm3) + AS2( movq mm3, mm2) + AS2( pmuludq mm2, k3) // a0*k3 + AS2( pmuludq mm3, mm7) // a0*k0 + AS2( movd [esp+8], mm0) + AS2( psrlq mm0, 32) + AS2( pmuludq mm7, mm5) // a1*k0 + AS2( pmuludq mm5, k3) // a1*k3 + AS2( paddq mm0, mm1) + AS2( movd mm1, a2) + AS2( pmuludq mm1, k2) // a2*k2 + AS2( paddq mm0, mm2) + AS2( paddq mm0, mm4) + AS2( movq mm4, mm0) + AS2( movd mm2, a3) + AS2( pmuludq mm2, mm6) // a3*k1 + AS2( pmuludq mm6, a0) // a0*k1 + AS2( psrlq mm0, 31) + AS2( paddq mm0, mm3) + AS2( movd mm3, [esp]) + AS2( paddq mm0, mm3) + AS2( movd mm3, a2) + AS2( pmuludq mm3, k3) // a2*k3 + AS2( paddq mm5, mm1) + AS2( movd mm1, a3) + AS2( pmuludq mm1, k2) // a3*k2 + AS2( paddq mm5, mm2) + AS2( movd mm2, [esp+4]) + AS2( psllq mm5, 1) + AS2( paddq mm0, mm5) + AS2( psllq mm4, 33) + AS2( movd a0, mm0) + AS2( psrlq mm0, 32) + AS2( paddq mm6, mm7) + AS2( movd mm7, [esp+8]) + AS2( paddq mm0, mm6) + AS2( paddq mm0, mm2) + AS2( paddq mm3, mm1) + AS2( psllq mm3, 1) + AS2( paddq mm0, mm3) + AS2( psrlq mm4, 1) + AS2( movd a1, mm0) + AS2( psrlq mm0, 32) + AS2( por mm4, mm7) + AS2( paddq mm0, mm4) + AS2( movq a2, mm0) +#undef a0 +#undef a1 +#undef a2 +#undef a3 +#undef k0 +#undef k1 +#undef k2 +#undef k3 + + ASL(3) + AS2( test ecx, ecx) + ASJ( jnz, 4, b) + + AS2( add esp, 12) + AS1( pop ebp) + AS1( emms) +#ifdef __GNUC__ + ".att_syntax prefix;" + AS2( mov %0, %%ebx) + : "=m" (temp) + : "m" (L1KeyLength), "c" (blocksRemainingInWord64), "S" (data), "D" (nhK+tagPart*2), "d" (m_isFirstBlock), "a" (polyS+tagPart*4) + : "memory", "cc" + ); +#endif +} +#endif + +#if VMAC_BOOL_WORD128 + #define DeclareNH(a) word128 a=0 + #define MUL64(rh,rl,i1,i2) {word128 p = word128(i1)*(i2); rh = word64(p>>64); rl = word64(p);} + #define AccumulateNH(a, b, c) a += word128(b)*(c) + #define Multiply128(r, i1, i2) r = word128(word64(i1)) * word64(i2) +#else + #if _MSC_VER >= 1400 && !defined(__INTEL_COMPILER) + #define MUL32(a, b) __emulu(word32(a), word32(b)) + #else + #define MUL32(a, b) ((word64)((word32)(a)) * (word32)(b)) + #endif + #if defined(CRYPTOPP_X64_ASM_AVAILABLE) + #define DeclareNH(a) word64 a##0=0, a##1=0 + #define MUL64(rh,rl,i1,i2) asm ("mulq %3" : "=a"(rl), "=d"(rh) : "a"(i1), "g"(i2) : "cc"); + #define AccumulateNH(a, b, c) asm ("mulq %3; addq %%rax, %0; adcq %%rdx, %1" : "+r"(a##0), "+r"(a##1) : "a"(b), "g"(c) : "%rdx", "cc"); + #define ADD128(rh,rl,ih,il) asm ("addq %3, %1; adcq %2, %0" : "+r"(rh),"+r"(rl) : "r"(ih),"r"(il) : "cc"); + #elif defined(_MSC_VER) && !CRYPTOPP_BOOL_SLOW_WORD64 + #define DeclareNH(a) word64 a##0=0, a##1=0 + #define MUL64(rh,rl,i1,i2) (rl) = _umul128(i1,i2,&(rh)); + #define AccumulateNH(a, b, c) {\ + word64 ph, pl;\ + pl = _umul128(b,c,&ph);\ + a##0 += pl;\ + a##1 += ph + (a##0 < pl);} + #else + #define VMAC_BOOL_32BIT 1 + #define DeclareNH(a) word64 a##0=0, a##1=0, a##2=0 + #define MUL64(rh,rl,i1,i2) \ + { word64 _i1 = (i1), _i2 = (i2); \ + word64 m1= MUL32(_i1,_i2>>32); \ + word64 m2= MUL32(_i1>>32,_i2); \ + rh = MUL32(_i1>>32,_i2>>32); \ + rl = MUL32(_i1,_i2); \ + ADD128(rh,rl,(m1 >> 32),(m1 << 32)); \ + ADD128(rh,rl,(m2 >> 32),(m2 << 32)); \ + } + #define AccumulateNH(a, b, c) {\ + word64 p = MUL32(b, c);\ + a##1 += word32((p)>>32);\ + a##0 += word32(p);\ + p = MUL32((b)>>32, c);\ + a##2 += word32((p)>>32);\ + a##1 += word32(p);\ + p = MUL32((b)>>32, (c)>>32);\ + a##2 += p;\ + p = MUL32(b, (c)>>32);\ + a##1 += word32(p);\ + a##2 += word32(p>>32);} + #endif +#endif +#ifndef VMAC_BOOL_32BIT + #define VMAC_BOOL_32BIT 0 +#endif +#ifndef ADD128 + #define ADD128(rh,rl,ih,il) \ + { word64 _il = (il); \ + (rl) += (_il); \ + (rh) += (ih) + ((rl) < (_il)); \ + } +#endif + +#if !(defined(_MSC_VER) && _MSC_VER < 1300) +template <bool T_128BitTag> +#endif +void VMAC_Base::VHASH_Update_Template(const word64 *data, size_t blocksRemainingInWord64) +{ + #define INNER_LOOP_ITERATION(j) {\ + word64 d0 = ConditionalByteReverse(LITTLE_ENDIAN_ORDER, data[i+2*j+0]);\ + word64 d1 = ConditionalByteReverse(LITTLE_ENDIAN_ORDER, data[i+2*j+1]);\ + AccumulateNH(nhA, d0+nhK[i+2*j+0], d1+nhK[i+2*j+1]);\ + if (T_128BitTag)\ + AccumulateNH(nhB, d0+nhK[i+2*j+2], d1+nhK[i+2*j+3]);\ + } + +#if (defined(_MSC_VER) && _MSC_VER < 1300) + bool T_128BitTag = m_is128; +#endif + size_t L1KeyLengthInWord64 = m_L1KeyLength / 8; + size_t innerLoopEnd = L1KeyLengthInWord64; + const word64 *nhK = m_nhKey(); + word64 *polyS = m_polyState(); + bool isFirstBlock = true; + size_t i; + + #if !VMAC_BOOL_32BIT + #if VMAC_BOOL_WORD128 + word128 a1, a2; + #else + word64 ah1, al1, ah2, al2; + #endif + word64 kh1, kl1, kh2, kl2; + kh1=(polyS+0*4+2)[0]; kl1=(polyS+0*4+2)[1]; + if (T_128BitTag) + { + kh2=(polyS+1*4+2)[0]; kl2=(polyS+1*4+2)[1]; + } + #endif + + do + { + DeclareNH(nhA); + DeclareNH(nhB); + + i = 0; + if (blocksRemainingInWord64 < L1KeyLengthInWord64) + { + if (blocksRemainingInWord64 % 8) + { + innerLoopEnd = blocksRemainingInWord64 % 8; + for (; i<innerLoopEnd; i+=2) + INNER_LOOP_ITERATION(0); + } + innerLoopEnd = blocksRemainingInWord64; + } + for (; i<innerLoopEnd; i+=8) + { + INNER_LOOP_ITERATION(0); + INNER_LOOP_ITERATION(1); + INNER_LOOP_ITERATION(2); + INNER_LOOP_ITERATION(3); + } + blocksRemainingInWord64 -= innerLoopEnd; + data += innerLoopEnd; + + #if VMAC_BOOL_32BIT + word32 nh0[2], nh1[2]; + word64 nh2[2]; + + nh0[0] = word32(nhA0); + nhA1 += (nhA0 >> 32); + nh1[0] = word32(nhA1); + nh2[0] = (nhA2 + (nhA1 >> 32)) & m62; + + if (T_128BitTag) + { + nh0[1] = word32(nhB0); + nhB1 += (nhB0 >> 32); + nh1[1] = word32(nhB1); + nh2[1] = (nhB2 + (nhB1 >> 32)) & m62; + } + + #define a0 (((word32 *)(polyS+i*4))[2+NativeByteOrder::ToEnum()]) + #define a1 (*(((word32 *)(polyS+i*4))+3-NativeByteOrder::ToEnum())) // workaround for GCC 3.2 + #define a2 (((word32 *)(polyS+i*4))[0+NativeByteOrder::ToEnum()]) + #define a3 (*(((word32 *)(polyS+i*4))+1-NativeByteOrder::ToEnum())) + #define aHi ((polyS+i*4)[0]) + #define k0 (((word32 *)(polyS+i*4+2))[2+NativeByteOrder::ToEnum()]) + #define k1 (*(((word32 *)(polyS+i*4+2))+3-NativeByteOrder::ToEnum())) + #define k2 (((word32 *)(polyS+i*4+2))[0+NativeByteOrder::ToEnum()]) + #define k3 (*(((word32 *)(polyS+i*4+2))+1-NativeByteOrder::ToEnum())) + #define kHi ((polyS+i*4+2)[0]) + + if (isFirstBlock) + { + isFirstBlock = false; + if (m_isFirstBlock) + { + m_isFirstBlock = false; + for (i=0; i<=(size_t)T_128BitTag; i++) + { + word64 t = (word64)nh0[i] + k0; + a0 = (word32)t; + t = (t >> 32) + nh1[i] + k1; + a1 = (word32)t; + aHi = (t >> 32) + nh2[i] + kHi; + } + continue; + } + } + for (i=0; i<=(size_t)T_128BitTag; i++) + { + word64 p, t; + word32 t2; + + p = MUL32(a3, 2*k3); + p += nh2[i]; + p += MUL32(a0, k2); + p += MUL32(a1, k1); + p += MUL32(a2, k0); + t2 = (word32)p; + p >>= 32; + p += MUL32(a0, k3); + p += MUL32(a1, k2); + p += MUL32(a2, k1); + p += MUL32(a3, k0); + t = (word64(word32(p) & 0x7fffffff) << 32) | t2; + p >>= 31; + p += nh0[i]; + p += MUL32(a0, k0); + p += MUL32(a1, 2*k3); + p += MUL32(a2, 2*k2); + p += MUL32(a3, 2*k1); + t2 = (word32)p; + p >>= 32; + p += nh1[i]; + p += MUL32(a0, k1); + p += MUL32(a1, k0); + p += MUL32(a2, 2*k3); + p += MUL32(a3, 2*k2); + a0 = t2; + a1 = (word32)p; + aHi = (p >> 32) + t; + } + + #undef a0 + #undef a1 + #undef a2 + #undef a3 + #undef aHi + #undef k0 + #undef k1 + #undef k2 + #undef k3 + #undef kHi + #else // #if VMAC_BOOL_32BIT + if (isFirstBlock) + { + isFirstBlock = false; + if (m_isFirstBlock) + { + m_isFirstBlock = false; + #if VMAC_BOOL_WORD128 + #define first_poly_step(a, kh, kl, m) a = (m & m126) + ((word128(kh) << 64) | kl) + + first_poly_step(a1, kh1, kl1, nhA); + if (T_128BitTag) + first_poly_step(a2, kh2, kl2, nhB); + #else + #define first_poly_step(ah, al, kh, kl, mh, ml) {\ + mh &= m62;\ + ADD128(mh, ml, kh, kl); \ + ah = mh; al = ml;} + + first_poly_step(ah1, al1, kh1, kl1, nhA1, nhA0); + if (T_128BitTag) + first_poly_step(ah2, al2, kh2, kl2, nhB1, nhB0); + #endif + continue; + } + else + { + #if VMAC_BOOL_WORD128 + a1 = (word128((polyS+0*4)[0]) << 64) | (polyS+0*4)[1]; + #else + ah1=(polyS+0*4)[0]; al1=(polyS+0*4)[1]; + #endif + if (T_128BitTag) + { + #if VMAC_BOOL_WORD128 + a2 = (word128((polyS+1*4)[0]) << 64) | (polyS+1*4)[1]; + #else + ah2=(polyS+1*4)[0]; al2=(polyS+1*4)[1]; + #endif + } + } + } + + #if VMAC_BOOL_WORD128 + #define poly_step(a, kh, kl, m) \ + { word128 t1, t2, t3, t4;\ + Multiply128(t2, a>>64, kl);\ + Multiply128(t3, a, kh);\ + Multiply128(t1, a, kl);\ + Multiply128(t4, a>>64, 2*kh);\ + t2 += t3;\ + t4 += t1;\ + t2 += t4>>64;\ + a = (word128(word64(t2)&m63) << 64) | word64(t4);\ + t2 *= 2;\ + a += m & m126;\ + a += t2>>64;} + + poly_step(a1, kh1, kl1, nhA); + if (T_128BitTag) + poly_step(a2, kh2, kl2, nhB); + #else + #define poly_step(ah, al, kh, kl, mh, ml) \ + { word64 t1h, t1l, t2h, t2l, t3h, t3l, z=0; \ + /* compute ab*cd, put bd into result registers */ \ + MUL64(t2h,t2l,ah,kl); \ + MUL64(t3h,t3l,al,kh); \ + MUL64(t1h,t1l,ah,2*kh); \ + MUL64(ah,al,al,kl); \ + /* add together ad + bc */ \ + ADD128(t2h,t2l,t3h,t3l); \ + /* add 2 * ac to result */ \ + ADD128(ah,al,t1h,t1l); \ + /* now (ah,al), (t2l,2*t2h) need summing */ \ + /* first add the high registers, carrying into t2h */ \ + ADD128(t2h,ah,z,t2l); \ + /* double t2h and add top bit of ah */ \ + t2h += t2h + (ah >> 63); \ + ah &= m63; \ + /* now add the low registers */ \ + mh &= m62; \ + ADD128(ah,al,mh,ml); \ + ADD128(ah,al,z,t2h); \ + } + + poly_step(ah1, al1, kh1, kl1, nhA1, nhA0); + if (T_128BitTag) + poly_step(ah2, al2, kh2, kl2, nhB1, nhB0); + #endif + #endif // #if VMAC_BOOL_32BIT + } while (blocksRemainingInWord64); + + #if VMAC_BOOL_WORD128 + (polyS+0*4)[0]=word64(a1>>64); (polyS+0*4)[1]=word64(a1); + if (T_128BitTag) + { + (polyS+1*4)[0]=word64(a2>>64); (polyS+1*4)[1]=word64(a2); + } + #elif !VMAC_BOOL_32BIT + (polyS+0*4)[0]=ah1; (polyS+0*4)[1]=al1; + if (T_128BitTag) + { + (polyS+1*4)[0]=ah2; (polyS+1*4)[1]=al2; + } + #endif +} + +inline void VMAC_Base::VHASH_Update(const word64 *data, size_t blocksRemainingInWord64) +{ +#if CRYPTOPP_BOOL_SSE2_ASM_AVAILABLE && CRYPTOPP_BOOL_X86 + if (HasSSE2()) + { + VHASH_Update_SSE2(data, blocksRemainingInWord64, 0); + if (m_is128) + VHASH_Update_SSE2(data, blocksRemainingInWord64, 1); + m_isFirstBlock = false; + } + else +#endif + { +#if defined(_MSC_VER) && _MSC_VER < 1300 + VHASH_Update_Template(data, blocksRemainingInWord64); +#else + if (m_is128) + VHASH_Update_Template<true>(data, blocksRemainingInWord64); + else + VHASH_Update_Template<false>(data, blocksRemainingInWord64); +#endif + } +} + +size_t VMAC_Base::HashMultipleBlocks(const word64 *data, size_t length) +{ + size_t remaining = ModPowerOf2(length, m_L1KeyLength); + VHASH_Update(data, (length-remaining)/8); + return remaining; +} + +static word64 L3Hash(const word64 *input, const word64 *l3Key, size_t len) +{ + word64 rh, rl, t, z=0; + word64 p1 = input[0], p2 = input[1]; + word64 k1 = l3Key[0], k2 = l3Key[1]; + + /* fully reduce (p1,p2)+(len,0) mod p127 */ + t = p1 >> 63; + p1 &= m63; + ADD128(p1, p2, len, t); + /* At this point, (p1,p2) is at most 2^127+(len<<64) */ + t = (p1 > m63) + ((p1 == m63) & (p2 == m64)); + ADD128(p1, p2, z, t); + p1 &= m63; + + /* compute (p1,p2)/(2^64-2^32) and (p1,p2)%(2^64-2^32) */ + t = p1 + (p2 >> 32); + t += (t >> 32); + t += (word32)t > 0xfffffffeU; + p1 += (t >> 32); + p2 += (p1 << 32); + + /* compute (p1+k1)%p64 and (p2+k2)%p64 */ + p1 += k1; + p1 += (0 - (p1 < k1)) & 257; + p2 += k2; + p2 += (0 - (p2 < k2)) & 257; + + /* compute (p1+k1)*(p2+k2)%p64 */ + MUL64(rh, rl, p1, p2); + t = rh >> 56; + ADD128(t, rl, z, rh); + rh <<= 8; + ADD128(t, rl, z, rh); + t += t << 8; + rl += t; + rl += (0 - (rl < t)) & 257; + rl += (0 - (rl > p64-1)) & 257; + return rl; +} + +void VMAC_Base::TruncatedFinal(byte *mac, size_t size) +{ + size_t len = ModPowerOf2(GetBitCountLo()/8, m_L1KeyLength); + + if (len) + { + memset(m_data()+len, 0, (0-len)%16); + VHASH_Update(DataBuf(), ((len+15)/16)*2); + len *= 8; // convert to bits + } + else if (m_isFirstBlock) + { + // special case for empty string + m_polyState()[0] = m_polyState()[2]; + m_polyState()[1] = m_polyState()[3]; + if (m_is128) + { + m_polyState()[4] = m_polyState()[6]; + m_polyState()[5] = m_polyState()[7]; + } + } + + if (m_is128) + { + word64 t[2]; + t[0] = L3Hash(m_polyState(), m_l3Key(), len) + GetWord<word64>(true, BIG_ENDIAN_ORDER, m_pad()); + t[1] = L3Hash(m_polyState()+4, m_l3Key()+2, len) + GetWord<word64>(true, BIG_ENDIAN_ORDER, m_pad()+8); + if (size == 16) + { + PutWord(false, BIG_ENDIAN_ORDER, mac, t[0]); + PutWord(false, BIG_ENDIAN_ORDER, mac+8, t[1]); + } + else + { + t[0] = ConditionalByteReverse(BIG_ENDIAN_ORDER, t[0]); + t[1] = ConditionalByteReverse(BIG_ENDIAN_ORDER, t[1]); + memcpy(mac, t, size); + } + } + else + { + word64 t = L3Hash(m_polyState(), m_l3Key(), len); + t += GetWord<word64>(true, BIG_ENDIAN_ORDER, m_pad() + (m_nonce()[IVSize()-1]&1) * 8); + if (size == 8) + PutWord(false, BIG_ENDIAN_ORDER, mac, t); + else + { + t = ConditionalByteReverse(BIG_ENDIAN_ORDER, t); + memcpy(mac, &t, size); + } + } +} + +NAMESPACE_END |