// integer.cpp - originally written and placed in the public domain by Wei Dai // contains public domain code contributed by Alister Lee and Leonard Janke // Notes by JW: The Integer class needs to do two things. First, it needs to set function // pointers on some platforms, like X86 and X64. The function pointers select a fast multiply // and addition based on the cpu. Second, it wants to create Integer::Zero(), Integer::One() // and Integer::Two(). The function pointers are initialized in the class InitializeInteger. // Wei's original code was much simpler. It uses the Singleton pattern, but it always produced // memory findings. The Singleton generates memory findings because it used for a Create on // First Use pattern. Resource destruction effectivley requires running resource acquisition // with dependencies in reverse. For resources provided through the Singletons, there is no way // to express the dependency order to safely destroy resources. // The difference in the changes below is we use platform and language specific remediations // if they are available. If not available, then we fall back to Wei's original code. If // NO_OS_DEPENDENCE is defined, then the library uses Wei's original code. // Under all versions of C++ on Linux and Microsoft platforms, we can use GCC's init_priority // or MSVC's init_seg(lib) to initialize the function pointers and create the Integers 0, 1 and 2 // after CRT startup. This avoids the Singletons and clears over half the reports of memory // leaks. However, it does not apply to Apple or Sun platforms. // C++11 allows us to use call_once to set the function pointers, and Integer does so when // init_priority and init_seg(lib) are not available. The class also uses the Singleton pattern // to ensure integers 0, 1 and 2 are available. The Singleton will produce memory findings, but // we don't have anything else to use in this case. // C++03 on platforms like Apple and Sun, we use a boolean flag to track when the function pointers // have been set based on the cpu. Its just a Nifty Counter in disguise, and its similar to using // the g_pAssignToInteger to track initialization. It has concurrency issues, but a race is not a // problem. It does not matter if two threads both set the same pointers. The Singleton pattern // is also used to ensure integers 0, 1 and 2 are available. The Singleton will produce memory // findings, but we don't have anything else to use in this case. // While not readily apparent, Integer does not need to inherit from InitializeInteger when // init_priority and init_seg(lib) are available. They just create an InitializePointers object // at the right time after CRT initialization. The additional class avoids the small runtime // overhead associated with checking the flags, and hides the detail from the interface. #include "pch.h" #include "config.h" #if CRYPTOPP_MSC_VERSION # pragma warning(disable: 4100) #endif #if CRYPTOPP_GCC_DIAGNOSTIC_AVAILABLE # pragma GCC diagnostic ignored "-Wunused" # pragma GCC diagnostic ignored "-Wunused-but-set-variable" #endif // Issue 340 #if CRYPTOPP_GCC_DIAGNOSTIC_AVAILABLE # pragma GCC diagnostic ignored "-Wconversion" # pragma GCC diagnostic ignored "-Wsign-conversion" #endif #ifndef CRYPTOPP_IMPORTS #include "integer.h" #include "secblock.h" #include "modarith.h" #include "nbtheory.h" #include "smartptr.h" #include "algparam.h" #include "filters.h" #include "stdcpp.h" #include "asn.h" #include "oids.h" #include "words.h" #include "pubkey.h" // for P1363_KDF2 #include "sha.h" #include "cpu.h" #include "misc.h" #include #if (_MSC_VER >= 1400) && !defined(_M_ARM) #include #endif #ifdef __DECCXX #include #endif // "Error: The operand ___LKDB cannot be assigned to", http://github.com/weidai11/cryptopp/issues/188 #if (__SUNPRO_CC >= 0x5130) # define MAYBE_CONST # define MAYBE_UNCONST_CAST(x) const_cast(x) #else # define MAYBE_CONST const # define MAYBE_UNCONST_CAST(x) x #endif // "Inline assembly operands don't work with .intel_syntax", // http://llvm.org/bugs/show_bug.cgi?id=24232 #if CRYPTOPP_BOOL_X32 || defined(CRYPTOPP_DISABLE_INTEL_ASM) # undef CRYPTOPP_X86_ASM_AVAILABLE # undef CRYPTOPP_X32_ASM_AVAILABLE # undef CRYPTOPP_X64_ASM_AVAILABLE # undef CRYPTOPP_BOOL_SSE2_ASM_AVAILABLE # undef CRYPTOPP_BOOL_SSSE3_ASM_AVAILABLE # define CRYPTOPP_BOOL_SSE2_ASM_AVAILABLE 0 # define CRYPTOPP_BOOL_SSSE3_ASM_AVAILABLE 0 #else # define CRYPTOPP_INTEGER_SSE2 (CRYPTOPP_BOOL_SSE2_ASM_AVAILABLE && (CRYPTOPP_BOOL_X86)) #endif // ***************** C++ Static Initialization ******************** NAMESPACE_BEGIN(CryptoPP) static void SetFunctionPointers(); #if defined(HAVE_GCC_INIT_PRIORITY) || defined(HAVE_MSC_INIT_PRIORITY) // Add InitializePointers to perform the work of setting pointers once. struct InitializePointers { InitializePointers() { SetFunctionPointers(); } }; // Leave InitializeInteger empty so no work is done. InitializeInteger::InitializeInteger() { } #elif defined(CRYPTOPP_CXX11_SYNCHRONIZATION) && defined(CRYPTOPP_CXX11_DYNAMIC_INIT) std::once_flag s_flag; InitializeInteger::InitializeInteger() { std::call_once(s_flag, []() { SetFunctionPointers(); }); } #else static bool s_flag; InitializeInteger::InitializeInteger() { MEMORY_BARRIER(); if (s_flag == false) { SetFunctionPointers(); s_flag = true; MEMORY_BARRIER(); } } #endif template struct NewInteger { Integer * operator()() const { return new Integer(i); } }; NAMESPACE_END ANONYMOUS_NAMESPACE_BEGIN #if defined(HAVE_GCC_INIT_PRIORITY) const CryptoPP::InitializePointers s_init __attribute__ ((init_priority (CRYPTOPP_INIT_PRIORITY + 30))) = CryptoPP::InitializePointers(); const CryptoPP::Integer s_zero __attribute__ ((init_priority (CRYPTOPP_INIT_PRIORITY + 31))) = CryptoPP::Integer(0L); const CryptoPP::Integer s_one __attribute__ ((init_priority (CRYPTOPP_INIT_PRIORITY + 32))) = CryptoPP::Integer(1L); const CryptoPP::Integer s_two __attribute__ ((init_priority (CRYPTOPP_INIT_PRIORITY + 33))) = CryptoPP::Integer(2L); #elif defined(HAVE_MSC_INIT_PRIORITY) #pragma warning(disable: 4075) #pragma init_seg(".CRT$XCU-030") const CryptoPP::InitializePointers s_init; const CryptoPP::Integer s_zero(0L); const CryptoPP::Integer s_one(1L); const CryptoPP::Integer s_two(2L); #pragma warning(default: 4075) #endif ANONYMOUS_NAMESPACE_END // ***************** Library code ******************** NAMESPACE_BEGIN(CryptoPP) inline static int Compare(const word *A, const word *B, size_t N) { while (N--) if (A[N] > B[N]) return 1; else if (A[N] < B[N]) return -1; return 0; } inline static int Increment(word *A, size_t N, word B=1) { CRYPTOPP_ASSERT(N); word t = A[0]; A[0] = t+B; if (A[0] >= t) return 0; for (unsigned i=1; i>(WORD_BITS-1)); d##0 = 2*d##0 + (c>>(WORD_BITS-1)); c *= 2; #endif #ifndef Acc2WordsBy2 #define Acc2WordsBy2(a, b) a##0 += b##0; a##1 += a##0 < b##0; a##1 += b##1; #endif #define AddWithCarry(u, a, b) {word t = a+b; u##0 = t + u##1; u##1 = (ta) + (u##0>t);} #define GetCarry(u) u##1 #define GetBorrow(u) u##1 #else #define Declare2Words(x) dword x; #if _MSC_VER >= 1400 && !defined(__INTEL_COMPILER) && !defined(_M_ARM) #define MultiplyWords(p, a, b) p = __emulu(a, b); #else #define MultiplyWords(p, a, b) p = (dword)a*b; #endif #define AssignWord(a, b) a = b; #define Add2WordsBy1(a, b, c) a = b + c; #define Acc2WordsBy2(a, b) a += b; #define LowWord(a) word(a) #define HighWord(a) word(a>>WORD_BITS) #define Double3Words(c, d) d = 2*d + (c>>(WORD_BITS-1)); c *= 2; #define AddWithCarry(u, a, b) u = dword(a) + b + GetCarry(u); #define SubtractWithBorrow(u, a, b) u = dword(a) - b - GetBorrow(u); #define GetCarry(u) HighWord(u) #define GetBorrow(u) word(u>>(WORD_BITS*2-1)) #endif #ifndef MulAcc #define MulAcc(c, d, a, b) MultiplyWords(p, a, b); Acc2WordsBy1(p, c); c = LowWord(p); Acc2WordsBy1(d, HighWord(p)); #endif #ifndef Acc2WordsBy1 #define Acc2WordsBy1(a, b) Add2WordsBy1(a, a, b) #endif #ifndef Acc3WordsBy2 #define Acc3WordsBy2(c, d, e) Acc2WordsBy1(e, c); c = LowWord(e); Add2WordsBy1(e, d, HighWord(e)); #endif class DWord { public: #if defined(CRYPTOPP_NATIVE_DWORD_AVAILABLE) DWord() : m_whole() { } #else DWord() : m_halfs() { } #endif #ifdef CRYPTOPP_NATIVE_DWORD_AVAILABLE explicit DWord(word low) : m_whole(low) { } #else explicit DWord(word low) : m_halfs() { m_halfs.low = low; } #endif #if defined(CRYPTOPP_NATIVE_DWORD_AVAILABLE) DWord(word low, word high) : m_whole() #else DWord(word low, word high) : m_halfs() #endif { #if defined(CRYPTOPP_NATIVE_DWORD_AVAILABLE) # if defined(IS_LITTLE_ENDIAN) const word t[2] = {low,high}; memcpy(&m_whole, &t, sizeof(m_whole)); # else const word t[2] = {high,low}; memcpy(&m_whole, &t, sizeof(m_whole)); # endif #else m_halfs.low = low; m_halfs.high = high; #endif } static DWord Multiply(word a, word b) { DWord r; #ifdef CRYPTOPP_NATIVE_DWORD_AVAILABLE r.m_whole = (dword)a * b; #elif defined(MultiplyWordsLoHi) MultiplyWordsLoHi(r.m_halfs.low, r.m_halfs.high, a, b); #else CRYPTOPP_ASSERT(0); #endif return r; } static DWord MultiplyAndAdd(word a, word b, word c) { DWord r = Multiply(a, b); return r += c; } DWord & operator+=(word a) { #ifdef CRYPTOPP_NATIVE_DWORD_AVAILABLE m_whole = m_whole + a; #else m_halfs.low += a; m_halfs.high += (m_halfs.low < a); #endif return *this; } DWord operator+(word a) { DWord r; #ifdef CRYPTOPP_NATIVE_DWORD_AVAILABLE r.m_whole = m_whole + a; #else r.m_halfs.low = m_halfs.low + a; r.m_halfs.high = m_halfs.high + (r.m_halfs.low < a); #endif return r; } DWord operator-(DWord a) { DWord r; #ifdef CRYPTOPP_NATIVE_DWORD_AVAILABLE r.m_whole = m_whole - a.m_whole; #else r.m_halfs.low = m_halfs.low - a.m_halfs.low; r.m_halfs.high = m_halfs.high - a.m_halfs.high - (r.m_halfs.low > m_halfs.low); #endif return r; } DWord operator-(word a) { DWord r; #ifdef CRYPTOPP_NATIVE_DWORD_AVAILABLE r.m_whole = m_whole - a; #else r.m_halfs.low = m_halfs.low - a; r.m_halfs.high = m_halfs.high - (r.m_halfs.low > m_halfs.low); #endif return r; } // returns quotient, which must fit in a word word operator/(word divisor); word operator%(word a); bool operator!() const { #ifdef CRYPTOPP_NATIVE_DWORD_AVAILABLE return !m_whole; #else return !m_halfs.high && !m_halfs.low; #endif } // TODO: When NATIVE_DWORD is in effect, we access high and low, which are inactive // union members, and that's UB. Also see http://stackoverflow.com/q/11373203. word GetLowHalf() const {return m_halfs.low;} word GetHighHalf() const {return m_halfs.high;} word GetHighHalfAsBorrow() const {return 0-m_halfs.high;} private: // Issue 274, "Types cannot be declared in anonymous union", // http://github.com/weidai11/cryptopp/issues/274 // Thanks to Martin Bonner at http://stackoverflow.com/a/39507183 struct half_words { #ifdef IS_LITTLE_ENDIAN word low; word high; #else word high; word low; #endif }; union { #ifdef CRYPTOPP_NATIVE_DWORD_AVAILABLE dword m_whole; #endif half_words m_halfs; }; }; class Word { public: Word() : m_whole(0) {} Word(word value) : m_whole(value) {} Word(hword low, hword high) : m_whole(low | (word(high) << (WORD_BITS/2))) {} static Word Multiply(hword a, hword b) { Word r; r.m_whole = (word)a * b; return r; } Word operator-(Word a) { Word r; r.m_whole = m_whole - a.m_whole; return r; } Word operator-(hword a) { Word r; r.m_whole = m_whole - a; return r; } // returns quotient, which must fit in a word hword operator/(hword divisor) { return hword(m_whole / divisor); } bool operator!() const { return !m_whole; } word GetWhole() const {return m_whole;} hword GetLowHalf() const {return hword(m_whole);} hword GetHighHalf() const {return hword(m_whole>>(WORD_BITS/2));} hword GetHighHalfAsBorrow() const {return 0-hword(m_whole>>(WORD_BITS/2));} private: word m_whole; }; // do a 3 word by 2 word divide, returns quotient and leaves remainder in A template S DivideThreeWordsByTwo(S *A, S B0, S B1, D *dummy=NULLPTR) { CRYPTOPP_UNUSED(dummy); // Assert {A[2],A[1]} < {B1,B0}, so quotient can fit in a S CRYPTOPP_ASSERT(A[2] < B1 || (A[2]==B1 && A[1] < B0)); // estimate the quotient: do a 2 S by 1 S divide. // Profiling tells us the original second case was dominant, so it was promoted to the first If statement. // The code change occurred at Commit dc99266599a0e72d. S Q; bool pre = (S(B1+1) == 0); if (B1 > 0 && !pre) Q = D(A[1], A[2]) / S(B1+1); else if (pre) Q = A[2]; else Q = D(A[0], A[1]) / B0; // now subtract Q*B from A D p = D::Multiply(B0, Q); D u = (D) A[0] - p.GetLowHalf(); A[0] = u.GetLowHalf(); u = (D) A[1] - p.GetHighHalf() - u.GetHighHalfAsBorrow() - D::Multiply(B1, Q); A[1] = u.GetLowHalf(); A[2] += u.GetHighHalf(); // Q <= actual quotient, so fix it while (A[2] || A[1] > B1 || (A[1]==B1 && A[0]>=B0)) { u = (D) A[0] - B0; A[0] = u.GetLowHalf(); u = (D) A[1] - B1 - u.GetHighHalfAsBorrow(); A[1] = u.GetLowHalf(); A[2] += u.GetHighHalf(); Q++; CRYPTOPP_ASSERT(Q); // shouldn't overflow } return Q; } // do a 4 word by 2 word divide, returns 2 word quotient in Q0 and Q1 template inline D DivideFourWordsByTwo(S *T, const D &Al, const D &Ah, const D &B) { // Profiling tells us the original second case was dominant, so it was promoted to the first If statement. // The code change occurred at Commit dc99266599a0e72d. if (!!B) { S Q[2]; T[0] = Al.GetLowHalf(); T[1] = Al.GetHighHalf(); T[2] = Ah.GetLowHalf(); T[3] = Ah.GetHighHalf(); Q[1] = DivideThreeWordsByTwo(T+1, B.GetLowHalf(), B.GetHighHalf()); Q[0] = DivideThreeWordsByTwo(T, B.GetLowHalf(), B.GetHighHalf()); return D(Q[0], Q[1]); } else // if divisor is 0, we assume divisor==2**(2*WORD_BITS) { return D(Ah.GetLowHalf(), Ah.GetHighHalf()); } } // returns quotient, which must fit in a word inline word DWord::operator/(word a) { #ifdef CRYPTOPP_NATIVE_DWORD_AVAILABLE return word(m_whole / a); #else hword r[4]; return DivideFourWordsByTwo(r, m_halfs.low, m_halfs.high, a).GetWhole(); #endif } inline word DWord::operator%(word a) { #ifdef CRYPTOPP_NATIVE_DWORD_AVAILABLE return word(m_whole % a); #else if (a < (word(1) << (WORD_BITS/2))) { hword h = hword(a); word r = m_halfs.high % h; r = ((m_halfs.low >> (WORD_BITS/2)) + (r << (WORD_BITS/2))) % h; return hword((hword(m_halfs.low) + (r << (WORD_BITS/2))) % h); } else { hword r[4]; DivideFourWordsByTwo(r, m_halfs.low, m_halfs.high, a); return Word(r[0], r[1]).GetWhole(); } #endif } // ******************************************************** // Use some tricks to share assembly code between MSVC, GCC, Clang and Sun CC. #if defined(__GNUC__) #define AddPrologue \ int result; \ __asm__ __volatile__ \ ( \ INTEL_NOPREFIX #define AddEpilogue \ ATT_PREFIX \ : "=a" (result)\ : "d" (C), "a" (A), "D" (B), "c" (N) \ : "%esi", "memory", "cc" \ );\ return result; #define MulPrologue \ __asm__ __volatile__ \ ( \ INTEL_NOPREFIX \ AS1( push ebx) \ AS2( mov ebx, edx) #define MulEpilogue \ AS1( pop ebx) \ ATT_PREFIX \ : \ : "d" (s_maskLow16), "c" (C), "a" (A), "D" (B) \ : "%esi", "memory", "cc" \ ); #define SquPrologue MulPrologue #define SquEpilogue \ AS1( pop ebx) \ ATT_PREFIX \ : \ : "d" (s_maskLow16), "c" (C), "a" (A) \ : "%esi", "%edi", "memory", "cc" \ ); #define TopPrologue MulPrologue #define TopEpilogue \ AS1( pop ebx) \ ATT_PREFIX \ : \ : "d" (s_maskLow16), "c" (C), "a" (A), "D" (B), "S" (L) \ : "memory", "cc" \ ); #else #define AddPrologue \ __asm push edi \ __asm push esi \ __asm mov eax, [esp+12] \ __asm mov edi, [esp+16] #define AddEpilogue \ __asm pop esi \ __asm pop edi \ __asm ret 8 #define SaveEBX #define RestoreEBX #define SquPrologue \ AS2( mov eax, A) \ AS2( mov ecx, C) \ SaveEBX \ AS2( lea ebx, s_maskLow16) #define MulPrologue \ AS2( mov eax, A) \ AS2( mov edi, B) \ AS2( mov ecx, C) \ SaveEBX \ AS2( lea ebx, s_maskLow16) #define TopPrologue \ AS2( mov eax, A) \ AS2( mov edi, B) \ AS2( mov ecx, C) \ AS2( mov esi, L) \ SaveEBX \ AS2( lea ebx, s_maskLow16) #define SquEpilogue RestoreEBX #define MulEpilogue RestoreEBX #define TopEpilogue RestoreEBX #endif #ifdef CRYPTOPP_X64_MASM_AVAILABLE extern "C" { int Baseline_Add(size_t N, word *C, const word *A, const word *B); int Baseline_Sub(size_t N, word *C, const word *A, const word *B); } #elif defined(CRYPTOPP_X64_ASM_AVAILABLE) && defined(__GNUC__) && defined(CRYPTOPP_WORD128_AVAILABLE) int Baseline_Add(size_t N, word *C, const word *A, const word *B) { word result; __asm__ __volatile__ ( INTEL_NOPREFIX AS1( neg %1) ASJ( jz, 1, f) AS2( mov %0,[%3+8*%1]) AS2( add %0,[%4+8*%1]) AS2( mov [%2+8*%1],%0) ASL(0) AS2( mov %0,[%3+8*%1+8]) AS2( adc %0,[%4+8*%1+8]) AS2( mov [%2+8*%1+8],%0) AS2( lea %1,[%1+2]) ASJ( jrcxz, 1, f) AS2( mov %0,[%3+8*%1]) AS2( adc %0,[%4+8*%1]) AS2( mov [%2+8*%1],%0) ASJ( jmp, 0, b) ASL(1) AS2( mov %0, 0) AS2( adc %0, %0) ATT_NOPREFIX : "=&r" (result), "+c" (N) : "r" (C+N), "r" (A+N), "r" (B+N) : "memory", "cc" ); return (int)result; } int Baseline_Sub(size_t N, word *C, const word *A, const word *B) { word result; __asm__ __volatile__ ( INTEL_NOPREFIX AS1( neg %1) ASJ( jz, 1, f) AS2( mov %0,[%3+8*%1]) AS2( sub %0,[%4+8*%1]) AS2( mov [%2+8*%1],%0) ASL(0) AS2( mov %0,[%3+8*%1+8]) AS2( sbb %0,[%4+8*%1+8]) AS2( mov [%2+8*%1+8],%0) AS2( lea %1,[%1+2]) ASJ( jrcxz, 1, f) AS2( mov %0,[%3+8*%1]) AS2( sbb %0,[%4+8*%1]) AS2( mov [%2+8*%1],%0) ASJ( jmp, 0, b) ASL(1) AS2( mov %0, 0) AS2( adc %0, %0) ATT_NOPREFIX : "=&r" (result), "+c" (N) : "r" (C+N), "r" (A+N), "r" (B+N) : "memory", "cc" ); return (int)result; } #elif defined(CRYPTOPP_X86_ASM_AVAILABLE) && CRYPTOPP_BOOL_X86 CRYPTOPP_NAKED int CRYPTOPP_FASTCALL Baseline_Add(size_t N, word *C, const word *A, const word *B) { AddPrologue // now: eax = A, edi = B, edx = C, ecx = N AS2( lea eax, [eax+4*ecx]) AS2( lea edi, [edi+4*ecx]) AS2( lea edx, [edx+4*ecx]) AS1( neg ecx) // ecx is negative index AS2( test ecx, 2) // this clears carry flag ASJ( jz, 0, f) AS2( sub ecx, 2) ASJ( jmp, 1, f) ASL(0) ASJ( jecxz, 2, f) // loop until ecx overflows and becomes zero AS2( mov esi,[eax+4*ecx]) AS2( adc esi,[edi+4*ecx]) AS2( mov [edx+4*ecx],esi) AS2( mov esi,[eax+4*ecx+4]) AS2( adc esi,[edi+4*ecx+4]) AS2( mov [edx+4*ecx+4],esi) ASL(1) AS2( mov esi,[eax+4*ecx+8]) AS2( adc esi,[edi+4*ecx+8]) AS2( mov [edx+4*ecx+8],esi) AS2( mov esi,[eax+4*ecx+12]) AS2( adc esi,[edi+4*ecx+12]) AS2( mov [edx+4*ecx+12],esi) AS2( lea ecx,[ecx+4]) // advance index, avoid inc which causes slowdown on Intel Core 2 ASJ( jmp, 0, b) ASL(2) AS2( mov eax, 0) AS1( setc al) // store carry into eax (return result register) AddEpilogue } CRYPTOPP_NAKED int CRYPTOPP_FASTCALL Baseline_Sub(size_t N, word *C, const word *A, const word *B) { AddPrologue // now: eax = A, edi = B, edx = C, ecx = N AS2( lea eax, [eax+4*ecx]) AS2( lea edi, [edi+4*ecx]) AS2( lea edx, [edx+4*ecx]) AS1( neg ecx) // ecx is negative index AS2( test ecx, 2) // this clears carry flag ASJ( jz, 0, f) AS2( sub ecx, 2) ASJ( jmp, 1, f) ASL(0) ASJ( jecxz, 2, f) // loop until ecx overflows and becomes zero AS2( mov esi,[eax+4*ecx]) AS2( sbb esi,[edi+4*ecx]) AS2( mov [edx+4*ecx],esi) AS2( mov esi,[eax+4*ecx+4]) AS2( sbb esi,[edi+4*ecx+4]) AS2( mov [edx+4*ecx+4],esi) ASL(1) AS2( mov esi,[eax+4*ecx+8]) AS2( sbb esi,[edi+4*ecx+8]) AS2( mov [edx+4*ecx+8],esi) AS2( mov esi,[eax+4*ecx+12]) AS2( sbb esi,[edi+4*ecx+12]) AS2( mov [edx+4*ecx+12],esi) AS2( lea ecx,[ecx+4]) // advance index, avoid inc which causes slowdown on Intel Core 2 ASJ( jmp, 0, b) ASL(2) AS2( mov eax, 0) AS1( setc al) // store carry into eax (return result register) AddEpilogue } #if CRYPTOPP_INTEGER_SSE2 CRYPTOPP_NAKED int CRYPTOPP_FASTCALL SSE2_Add(size_t N, word *C, const word *A, const word *B) { AddPrologue // now: eax = A, edi = B, edx = C, ecx = N AS2( lea eax, [eax+4*ecx]) AS2( lea edi, [edi+4*ecx]) AS2( lea edx, [edx+4*ecx]) AS1( neg ecx) // ecx is negative index AS2( pxor mm2, mm2) ASJ( jz, 2, f) AS2( test ecx, 2) // this clears carry flag ASJ( jz, 0, f) AS2( sub ecx, 2) ASJ( jmp, 1, f) ASL(0) AS2( movd mm0, DWORD PTR [eax+4*ecx]) AS2( movd mm1, DWORD PTR [edi+4*ecx]) AS2( paddq mm0, mm1) AS2( paddq mm2, mm0) AS2( movd DWORD PTR [edx+4*ecx], mm2) AS2( psrlq mm2, 32) AS2( movd mm0, DWORD PTR [eax+4*ecx+4]) AS2( movd mm1, DWORD PTR [edi+4*ecx+4]) AS2( paddq mm0, mm1) AS2( paddq mm2, mm0) AS2( movd DWORD PTR [edx+4*ecx+4], mm2) AS2( psrlq mm2, 32) ASL(1) AS2( movd mm0, DWORD PTR [eax+4*ecx+8]) AS2( movd mm1, DWORD PTR [edi+4*ecx+8]) AS2( paddq mm0, mm1) AS2( paddq mm2, mm0) AS2( movd DWORD PTR [edx+4*ecx+8], mm2) AS2( psrlq mm2, 32) AS2( movd mm0, DWORD PTR [eax+4*ecx+12]) AS2( movd mm1, DWORD PTR [edi+4*ecx+12]) AS2( paddq mm0, mm1) AS2( paddq mm2, mm0) AS2( movd DWORD PTR [edx+4*ecx+12], mm2) AS2( psrlq mm2, 32) AS2( add ecx, 4) ASJ( jnz, 0, b) ASL(2) AS2( movd eax, mm2) AS1( emms) AddEpilogue } CRYPTOPP_NAKED int CRYPTOPP_FASTCALL SSE2_Sub(size_t N, word *C, const word *A, const word *B) { AddPrologue // now: eax = A, edi = B, edx = C, ecx = N AS2( lea eax, [eax+4*ecx]) AS2( lea edi, [edi+4*ecx]) AS2( lea edx, [edx+4*ecx]) AS1( neg ecx) // ecx is negative index AS2( pxor mm2, mm2) ASJ( jz, 2, f) AS2( test ecx, 2) // this clears carry flag ASJ( jz, 0, f) AS2( sub ecx, 2) ASJ( jmp, 1, f) ASL(0) AS2( movd mm0, DWORD PTR [eax+4*ecx]) AS2( movd mm1, DWORD PTR [edi+4*ecx]) AS2( psubq mm0, mm1) AS2( psubq mm0, mm2) AS2( movd DWORD PTR [edx+4*ecx], mm0) AS2( psrlq mm0, 63) AS2( movd mm2, DWORD PTR [eax+4*ecx+4]) AS2( movd mm1, DWORD PTR [edi+4*ecx+4]) AS2( psubq mm2, mm1) AS2( psubq mm2, mm0) AS2( movd DWORD PTR [edx+4*ecx+4], mm2) AS2( psrlq mm2, 63) ASL(1) AS2( movd mm0, DWORD PTR [eax+4*ecx+8]) AS2( movd mm1, DWORD PTR [edi+4*ecx+8]) AS2( psubq mm0, mm1) AS2( psubq mm0, mm2) AS2( movd DWORD PTR [edx+4*ecx+8], mm0) AS2( psrlq mm0, 63) AS2( movd mm2, DWORD PTR [eax+4*ecx+12]) AS2( movd mm1, DWORD PTR [edi+4*ecx+12]) AS2( psubq mm2, mm1) AS2( psubq mm2, mm0) AS2( movd DWORD PTR [edx+4*ecx+12], mm2) AS2( psrlq mm2, 63) AS2( add ecx, 4) ASJ( jnz, 0, b) ASL(2) AS2( movd eax, mm2) AS1( emms) AddEpilogue } #endif // CRYPTOPP_INTEGER_SSE2 #else // CRYPTOPP_BOOL_SSE2_ASM_AVAILABLE int CRYPTOPP_FASTCALL Baseline_Add(size_t N, word *C, const word *A, const word *B) { CRYPTOPP_ASSERT (N%2 == 0); Declare2Words(u); AssignWord(u, 0); for (size_t i=0; i=2 && N%2==0); if (N <= s_recursionLimit) s_pMul[N/4](R, A, B); else { const size_t N2 = N/2; size_t AN2 = Compare(A0, A1, N2) > 0 ? 0 : N2; Subtract(R0, A + AN2, A + (N2 ^ AN2), N2); size_t BN2 = Compare(B0, B1, N2) > 0 ? 0 : N2; Subtract(R1, B + BN2, B + (N2 ^ BN2), N2); RecursiveMultiply(R2, T2, A1, B1, N2); RecursiveMultiply(T0, T2, R0, R1, N2); RecursiveMultiply(R0, T2, A0, B0, N2); // now T[01] holds (A1-A0)*(B0-B1), R[01] holds A0*B0, R[23] holds A1*B1 int c2 = Add(R2, R2, R1, N2); int c3 = c2; c2 += Add(R1, R2, R0, N2); c3 += Add(R2, R2, R3, N2); if (AN2 == BN2) c3 -= Subtract(R1, R1, T0, N); else c3 += Add(R1, R1, T0, N); c3 += Increment(R2, N2, c2); CRYPTOPP_ASSERT (c3 >= 0 && c3 <= 2); Increment(R3, N2, c3); } } // R[2*N] - result = A*A // T[2*N] - temporary work space // A[N] --- number to be squared void RecursiveSquare(word *R, word *T, const word *A, size_t N) { CRYPTOPP_ASSERT(N && N%2==0); if (N <= s_recursionLimit) s_pSqu[N/4](R, A); else { const size_t N2 = N/2; RecursiveSquare(R0, T2, A0, N2); RecursiveSquare(R2, T2, A1, N2); RecursiveMultiply(T0, T2, A0, A1, N2); int carry = Add(R1, R1, T0, N); carry += Add(R1, R1, T0, N); Increment(R3, N2, carry); } } // R[N] - bottom half of A*B // T[3*N/2] - temporary work space // A[N] - multiplier // B[N] - multiplicant void RecursiveMultiplyBottom(word *R, word *T, const word *A, const word *B, size_t N) { CRYPTOPP_ASSERT(N>=2 && N%2==0); if (N <= s_recursionLimit) s_pBot[N/4](R, A, B); else { const size_t N2 = N/2; RecursiveMultiply(R, T, A0, B0, N2); RecursiveMultiplyBottom(T0, T1, A1, B0, N2); Add(R1, R1, T0, N2); RecursiveMultiplyBottom(T0, T1, A0, B1, N2); Add(R1, R1, T0, N2); } } // R[N] --- upper half of A*B // T[2*N] - temporary work space // L[N] --- lower half of A*B // A[N] --- multiplier // B[N] --- multiplicant void MultiplyTop(word *R, word *T, const word *L, const word *A, const word *B, size_t N) { CRYPTOPP_ASSERT(N>=2 && N%2==0); if (N <= s_recursionLimit) s_pTop[N/4](R, A, B, L[N-1]); else { const size_t N2 = N/2; size_t AN2 = Compare(A0, A1, N2) > 0 ? 0 : N2; Subtract(R0, A + AN2, A + (N2 ^ AN2), N2); size_t BN2 = Compare(B0, B1, N2) > 0 ? 0 : N2; Subtract(R1, B + BN2, B + (N2 ^ BN2), N2); RecursiveMultiply(T0, T2, R0, R1, N2); RecursiveMultiply(R0, T2, A1, B1, N2); // now T[01] holds (A1-A0)*(B0-B1) = A1*B0+A0*B1-A1*B1-A0*B0, R[01] holds A1*B1 int t, c3; int c2 = Subtract(T2, L+N2, L, N2); if (AN2 == BN2) { c2 -= Add(T2, T2, T0, N2); t = (Compare(T2, R0, N2) == -1); c3 = t - Subtract(T2, T2, T1, N2); } else { c2 += Subtract(T2, T2, T0, N2); t = (Compare(T2, R0, N2) == -1); c3 = t + Add(T2, T2, T1, N2); } c2 += t; if (c2 >= 0) c3 += Increment(T2, N2, c2); else c3 -= Decrement(T2, N2, -c2); c3 += Add(R0, T2, R1, N2); CRYPTOPP_ASSERT (c3 >= 0 && c3 <= 2); Increment(R1, N2, c3); } } inline void Multiply(word *R, word *T, const word *A, const word *B, size_t N) { RecursiveMultiply(R, T, A, B, N); } inline void Square(word *R, word *T, const word *A, size_t N) { RecursiveSquare(R, T, A, N); } inline void MultiplyBottom(word *R, word *T, const word *A, const word *B, size_t N) { RecursiveMultiplyBottom(R, T, A, B, N); } // R[NA+NB] - result = A*B // T[NA+NB] - temporary work space // A[NA] ---- multiplier // B[NB] ---- multiplicant void AsymmetricMultiply(word *R, word *T, const word *A, size_t NA, const word *B, size_t NB) { if (NA == NB) { // Profiling tells us the original second case was dominant, so it was promoted to the first If statement. // The code change occurred at Commit dc99266599a0e72d. if (A != B) Multiply(R, T, A, B, NA); else Square(R, T, A, NA); return; } if (NA > NB) { std::swap(A, B); std::swap(NA, NB); } CRYPTOPP_ASSERT(NB % NA == 0); if (NA==2 && !A[1]) { // Profiling tells us the original Default case was dominant, so it was promoted to the first Case statement. // The code change occurred at Commit dc99266599a0e72d. switch (A[0]) { default: R[NB] = LinearMultiply(R, B, A[0], NB); R[NB+1] = 0; return; case 0: SetWords(R, 0, NB+2); return; case 1: CopyWords(R, B, NB); R[NB] = R[NB+1] = 0; return; } } size_t i; if ((NB/NA)%2 == 0) { Multiply(R, T, A, B, NA); CopyWords(T+2*NA, R+NA, NA); for (i=2*NA; i=4); #define M0 M #define M1 (M+N2) #define V0 V #define V1 (V+N2) #define X0 X #define X1 (X+N2) #define X2 (X+N) #define X3 (X+N+N2) const size_t N2 = N/2; Multiply(T0, T2, V0, X3, N2); int c2 = Add(T0, T0, X0, N); MultiplyBottom(T3, T2, T0, U, N2); MultiplyTop(T2, R, T0, T3, M0, N2); c2 -= Subtract(T2, T1, T2, N2); Multiply(T0, R, T3, M1, N2); c2 -= Subtract(T0, T2, T0, N2); int c3 = -(int)Subtract(T1, X2, T1, N2); Multiply(R0, T2, V1, X3, N2); c3 += Add(R, R, T, N); if (c2>0) c3 += Increment(R1, N2); else if (c2<0) c3 -= Decrement(R1, N2, -c2); CRYPTOPP_ASSERT(c3>=-1 && c3<=1); if (c3>0) Subtract(R, R, M, N); else if (c3<0) Add(R, R, M, N); #undef M0 #undef M1 #undef V0 #undef V1 #undef X0 #undef X1 #undef X2 #undef X3 } #undef A0 #undef A1 #undef B0 #undef B1 #undef T0 #undef T1 #undef T2 #undef T3 #undef R0 #undef R1 #undef R2 #undef R3 /* // do a 3 word by 2 word divide, returns quotient and leaves remainder in A static word SubatomicDivide(word *A, word B0, word B1) { // Assert {A[2],A[1]} < {B1,B0}, so quotient can fit in a word CRYPTOPP_ASSERT(A[2] < B1 || (A[2]==B1 && A[1] < B0)); // estimate the quotient: do a 2 word by 1 word divide word Q; if (B1+1 == 0) Q = A[2]; else Q = DWord(A[1], A[2]).DividedBy(B1+1); // now subtract Q*B from A DWord p = DWord::Multiply(B0, Q); DWord u = (DWord) A[0] - p.GetLowHalf(); A[0] = u.GetLowHalf(); u = (DWord) A[1] - p.GetHighHalf() - u.GetHighHalfAsBorrow() - DWord::Multiply(B1, Q); A[1] = u.GetLowHalf(); A[2] += u.GetHighHalf(); // Q <= actual quotient, so fix it while (A[2] || A[1] > B1 || (A[1]==B1 && A[0]>=B0)) { u = (DWord) A[0] - B0; A[0] = u.GetLowHalf(); u = (DWord) A[1] - B1 - u.GetHighHalfAsBorrow(); A[1] = u.GetLowHalf(); A[2] += u.GetHighHalf(); Q++; CRYPTOPP_ASSERT(Q); // shouldn't overflow } return Q; } // do a 4 word by 2 word divide, returns 2 word quotient in Q0 and Q1 static inline void AtomicDivide(word *Q, const word *A, const word *B) { if (!B[0] && !B[1]) // if divisor is 0, we assume divisor==2**(2*WORD_BITS) { Q[0] = A[2]; Q[1] = A[3]; } else { word T[4]; T[0] = A[0]; T[1] = A[1]; T[2] = A[2]; T[3] = A[3]; Q[1] = SubatomicDivide(T+1, B[0], B[1]); Q[0] = SubatomicDivide(T, B[0], B[1]); #if defined(CRYPTOPP_DEBUG) // multiply quotient and divisor and add remainder, make sure it equals dividend CRYPTOPP_ASSERT(!T[2] && !T[3] && (T[1] < B[1] || (T[1]==B[1] && T[0](T, DWord(A[0], A[1]), DWord(A[2], A[3]), DWord(B[0], B[1])); Q[0] = q.GetLowHalf(); Q[1] = q.GetHighHalf(); #if defined(CRYPTOPP_DEBUG) if (B[0] || B[1]) { // multiply quotient and divisor and add remainder, make sure it equals dividend CRYPTOPP_ASSERT(!T[2] && !T[3] && (T[1] < B[1] || (T[1]==B[1] && T[0]= 0) { R[N] -= Subtract(R, R, B, N); Q[1] += (++Q[0]==0); CRYPTOPP_ASSERT(Q[0] || Q[1]); // no overflow } } // R[NB] -------- remainder = A%B // Q[NA-NB+2] --- quotient = A/B // T[NA+3*(NB+2)] - temp work space // A[NA] -------- dividend // B[NB] -------- divisor void Divide(word *R, word *Q, word *T, const word *A, size_t NA, const word *B, size_t NB) { CRYPTOPP_ASSERT(NA && NB && NA%2==0 && NB%2==0); CRYPTOPP_ASSERT(B[NB-1] || B[NB-2]); CRYPTOPP_ASSERT(NB <= NA); // set up temporary work space word *const TA=T; word *const TB=T+NA+2; word *const TP=T+NA+2+NB; // copy B into TB and normalize it so that TB has highest bit set to 1 unsigned shiftWords = (B[NB-1]==0); TB[0] = TB[NB-1] = 0; CopyWords(TB+shiftWords, B, NB-shiftWords); unsigned shiftBits = WORD_BITS - BitPrecision(TB[NB-1]); CRYPTOPP_ASSERT(shiftBits < WORD_BITS); ShiftWordsLeftByBits(TB, NB, shiftBits); // copy A into TA and normalize it TA[0] = TA[NA] = TA[NA+1] = 0; CopyWords(TA+shiftWords, A, NA); ShiftWordsLeftByBits(TA, NA+2, shiftBits); if (TA[NA+1]==0 && TA[NA] <= 1) { Q[NA-NB+1] = Q[NA-NB] = 0; while (TA[NA] || Compare(TA+NA-NB, TB, NB) >= 0) { TA[NA] -= Subtract(TA+NA-NB, TA+NA-NB, TB, NB); ++Q[NA-NB]; } } else { NA+=2; CRYPTOPP_ASSERT(Compare(TA+NA-NB, TB, NB) < 0); } word BT[2]; BT[0] = TB[NB-2] + 1; BT[1] = TB[NB-1] + (BT[0]==0); // start reducing TA mod TB, 2 words at a time for (size_t i=NA-2; i>=NB; i-=2) { AtomicDivide(Q+i-NB, TA+i-2, BT); CorrectQuotientEstimate(TA+i-NB, TP, Q+i-NB, TB, NB); } // copy TA into R, and denormalize it CopyWords(R, TA+shiftWords, NB); ShiftWordsRightByBits(R, NB, shiftBits); } static inline size_t EvenWordCount(const word *X, size_t N) { while (N && X[N-2]==0 && X[N-1]==0) N-=2; return N; } // return k // R[N] --- result = A^(-1) * 2^k mod M // T[4*N] - temporary work space // A[NA] -- number to take inverse of // M[N] --- modulus unsigned int AlmostInverse(word *R, word *T, const word *A, size_t NA, const word *M, size_t N) { CRYPTOPP_ASSERT(NA<=N && N && N%2==0); word *b = T; word *c = T+N; word *f = T+2*N; word *g = T+3*N; size_t bcLen=2, fgLen=EvenWordCount(M, N); unsigned int k=0; bool s=false; SetWords(T, 0, 3*N); b[0]=1; CopyWords(f, A, NA); CopyWords(g, M, N); while (1) { word t=f[0]; while (!t) { if (EvenWordCount(f, fgLen)==0) { SetWords(R, 0, N); return 0; } ShiftWordsRightByWords(f, fgLen, 1); bcLen += 2 * (c[bcLen-1] != 0); CRYPTOPP_ASSERT(bcLen <= N); ShiftWordsLeftByWords(c, bcLen, 1); k+=WORD_BITS; t=f[0]; } // t must be non-0; otherwise undefined. unsigned int i = TrailingZeros(t); t >>= i; k += i; if (t==1 && f[1]==0 && EvenWordCount(f+2, fgLen-2)==0) { if (s) Subtract(R, M, b, N); else CopyWords(R, b, N); return k; } ShiftWordsRightByBits(f, fgLen, i); t = ShiftWordsLeftByBits(c, bcLen, i); c[bcLen] += t; bcLen += 2 * (t!=0); CRYPTOPP_ASSERT(bcLen <= N); bool swap = Compare(f, g, fgLen)==-1; ConditionalSwapPointers(swap, f, g); ConditionalSwapPointers(swap, b, c); s ^= swap; fgLen -= 2 * !(f[fgLen-2] | f[fgLen-1]); Subtract(f, f, g, fgLen); t = Add(b, b, c, bcLen); b[bcLen] += t; bcLen += 2*t; CRYPTOPP_ASSERT(bcLen <= N); } } // R[N] - result = A/(2^k) mod M // A[N] - input // M[N] - modulus void DivideByPower2Mod(word *R, const word *A, size_t k, const word *M, size_t N) { CopyWords(R, A, N); while (k--) { if (R[0]%2==0) ShiftWordsRightByBits(R, N, 1); else { word carry = Add(R, R, M, N); ShiftWordsRightByBits(R, N, 1); R[N-1] += carry<<(WORD_BITS-1); } } } // R[N] - result = A*(2^k) mod M // A[N] - input // M[N] - modulus void MultiplyByPower2Mod(word *R, const word *A, size_t k, const word *M, size_t N) { CopyWords(R, A, N); while (k--) if (ShiftWordsLeftByBits(R, N, 1) || Compare(R, M, N)>=0) Subtract(R, R, M, N); } // ****************************************************************** static const unsigned int RoundupSizeTable[] = {2, 2, 2, 4, 4, 8, 8, 8, 8}; static inline size_t RoundupSize(size_t n) { if (n<=8) return RoundupSizeTable[n]; else if (n<=16) return 16; else if (n<=32) return 32; else if (n<=64) return 64; else return size_t(1) << BitPrecision(n-1); } Integer::Integer() : reg(2), sign(POSITIVE) { reg[0] = reg[1] = 0; } Integer::Integer(const Integer& t) : reg(RoundupSize(t.WordCount())), sign(t.sign) { CopyWords(reg, t.reg, reg.size()); } Integer::Integer(Sign s, lword value) : reg(2), sign(s) { reg[0] = word(value); reg[1] = word(SafeRightShift(value)); } Integer::Integer(signed long value) : reg(2) { if (value >= 0) sign = POSITIVE; else { sign = NEGATIVE; value = -value; } reg[0] = word(value); reg[1] = word(SafeRightShift((unsigned long)value)); } Integer::Integer(Sign s, word high, word low) : reg(2), sign(s) { reg[0] = low; reg[1] = high; } bool Integer::IsConvertableToLong() const { if (ByteCount() > sizeof(long)) return false; unsigned long value = (unsigned long)reg[0]; value += SafeLeftShift((unsigned long)reg[1]); if (sign==POSITIVE) return (signed long)value >= 0; else return -(signed long)value < 0; } signed long Integer::ConvertToLong() const { CRYPTOPP_ASSERT(IsConvertableToLong()); unsigned long value = (unsigned long)reg[0]; value += SafeLeftShift((unsigned long)reg[1]); return sign==POSITIVE ? value : -(signed long)value; } Integer::Integer(BufferedTransformation &encodedInteger, size_t byteCount, Signedness s, ByteOrder o) { CRYPTOPP_ASSERT(o == BIG_ENDIAN_ORDER || o == LITTLE_ENDIAN_ORDER); if (o == LITTLE_ENDIAN_ORDER) { SecByteBlock block(byteCount); encodedInteger.Get(block, block.size()); std::reverse(block.begin(), block.begin()+block.size()); Decode(block.begin(), block.size(), s); return; } Decode(encodedInteger, byteCount, s); } Integer::Integer(const byte *encodedInteger, size_t byteCount, Signedness s, ByteOrder o) { CRYPTOPP_ASSERT(encodedInteger && byteCount); // NULL buffer CRYPTOPP_ASSERT(o == BIG_ENDIAN_ORDER || o == LITTLE_ENDIAN_ORDER); if (o == LITTLE_ENDIAN_ORDER) { SecByteBlock block(byteCount); #if (CRYPTOPP_MSC_VERSION >= 1410) std::reverse_copy(encodedInteger, encodedInteger+byteCount, stdext::make_checked_array_iterator(block.begin(), block.size())); #else std::reverse_copy(encodedInteger, encodedInteger+byteCount, block.begin()); #endif Decode(block.begin(), block.size(), s); return; } Decode(encodedInteger, byteCount, s); } Integer::Integer(BufferedTransformation &bt) { BERDecode(bt); } Integer::Integer(RandomNumberGenerator &rng, size_t bitcount) { Randomize(rng, bitcount); } Integer::Integer(RandomNumberGenerator &rng, const Integer &min, const Integer &max, RandomNumberType rnType, const Integer &equiv, const Integer &mod) { if (!Randomize(rng, min, max, rnType, equiv, mod)) throw Integer::RandomNumberNotFound(); } Integer Integer::Power2(size_t e) { Integer r((word)0, BitsToWords(e+1)); r.SetBit(e); return r; } const Integer &Integer::Zero() { #if defined(HAVE_GCC_INIT_PRIORITY) || defined(HAVE_MSC_INIT_PRIORITY) return s_zero; #else return Singleton >().Ref(); #endif } const Integer &Integer::One() { #if defined(HAVE_GCC_INIT_PRIORITY) || defined(HAVE_MSC_INIT_PRIORITY) return s_one; #else return Singleton >().Ref(); #endif } const Integer &Integer::Two() { #if defined(HAVE_GCC_INIT_PRIORITY) || defined(HAVE_MSC_INIT_PRIORITY) return s_two; #else return Singleton >().Ref(); #endif } bool Integer::operator!() const { return IsNegative() ? false : (reg[0]==0 && WordCount()==0); } Integer& Integer::operator=(const Integer& t) { if (this != &t) { if (reg.size() != t.reg.size() || t.reg[t.reg.size()/2] == 0) reg.New(RoundupSize(t.WordCount())); CopyWords(reg, t.reg, reg.size()); sign = t.sign; } return *this; } bool Integer::GetBit(size_t n) const { // Profiling tells us the original Else was dominant, so it was promoted to the first If statement. // The code change occurred at Commit dc99266599a0e72d. if (n/WORD_BITS < reg.size()) return bool((reg[n/WORD_BITS] >> (n % WORD_BITS)) & 1); else return 0; } void Integer::SetBit(size_t n, bool value) { if (value) { reg.CleanGrow(RoundupSize(BitsToWords(n+1))); reg[n/WORD_BITS] |= (word(1) << (n%WORD_BITS)); } else { if (n/WORD_BITS < reg.size()) reg[n/WORD_BITS] &= ~(word(1) << (n%WORD_BITS)); } } byte Integer::GetByte(size_t n) const { // Profiling tells us the original Else was dominant, so it was promoted to the first If statement. // The code change occurred at Commit dc99266599a0e72d. if (n/WORD_SIZE < reg.size()) return byte(reg[n/WORD_SIZE] >> ((n%WORD_SIZE)*8)); else return 0; } void Integer::SetByte(size_t n, byte value) { reg.CleanGrow(RoundupSize(BytesToWords(n+1))); reg[n/WORD_SIZE] &= ~(word(0xff) << 8*(n%WORD_SIZE)); reg[n/WORD_SIZE] |= (word(value) << 8*(n%WORD_SIZE)); } lword Integer::GetBits(size_t i, size_t n) const { lword v = 0; CRYPTOPP_ASSERT(n <= sizeof(v)*8); for (unsigned int j=0; j static Integer StringToInteger(const T *str, ByteOrder order) { CRYPTOPP_ASSERT( order == BIG_ENDIAN_ORDER || order == LITTLE_ENDIAN_ORDER ); int radix, sign = 1; // GCC workaround // std::char_traits::length() not defined in GCC 3.2 and STLport 4.5.3 unsigned int length; for (length = 0; str[length] != 0; length++) {} Integer v; if (length == 0) return Integer::Zero(); switch (str[length-1]) { case 'h': case 'H': radix=16; break; case 'o': case 'O': radix=8; break; case 'b': case 'B': radix=2; break; default: radix=10; } // 'str' is of length 1 or more if (str[0] == '-') { sign = -1; str += 1, length -= 1; } if (length > 2 && str[0] == '0' && (str[1] == 'x' || str[1] == 'X')) { radix = 16; str += 2, length -= 2; } if (order == BIG_ENDIAN_ORDER) { for (unsigned int i=0; i(str[i]); // Profiling showd the second and third Else needed to be swapped // The code change occurred at Commit dc99266599a0e72d. if (ch >= '0' && ch <= '9') digit = ch - '0'; else if (ch >= 'a' && ch <= 'f') digit = ch - 'a' + 10; else if (ch >= 'A' && ch <= 'F') digit = ch - 'A' + 10; else digit = radix; if (digit < radix) { v *= radix; v += digit; } } } else if (radix == 16 && order == LITTLE_ENDIAN_ORDER) { // Nibble high, low and count unsigned int nh = 0, nl = 0, nc = 0; Integer position(Integer::One()); for (unsigned int i=0; i(str[i]); if (ch >= '0' && ch <= '9') digit = ch - '0'; else if (ch >= 'a' && ch <= 'f') digit = ch - 'a' + 10; else if (ch >= 'A' && ch <= 'F') digit = ch - 'A' + 10; else digit = radix; if (digit < radix) { if (nc++ == 0) nh = digit; else nl = digit; if (nc == 2) { v += position * (nh << 4 | nl); nc = 0, position <<= 8; } } } if (nc == 1) v += nh * position; } else // LITTLE_ENDIAN_ORDER && radix != 16 { for (int i=static_cast(length)-1; i>=0; i--) { int digit, ch = static_cast(str[i]); if (ch >= '0' && ch <= '9') digit = ch - '0'; else if (ch >= 'a' && ch <= 'f') digit = ch - 'a' + 10; else if (ch >= 'A' && ch <= 'F') digit = ch - 'A' + 10; else digit = radix; if (digit < radix) { v *= radix; v += digit; } } } if (sign == -1) v.Negate(); return v; } Integer::Integer(const char *str, ByteOrder order) : reg(2), sign(POSITIVE) { *this = StringToInteger(str,order); } Integer::Integer(const wchar_t *str, ByteOrder order) : reg(2), sign(POSITIVE) { *this = StringToInteger(str,order); } unsigned int Integer::WordCount() const { return (unsigned int)CountWords(reg, reg.size()); } unsigned int Integer::ByteCount() const { unsigned wordCount = WordCount(); if (wordCount) return (wordCount-1)*WORD_SIZE + BytePrecision(reg[wordCount-1]); else return 0; } unsigned int Integer::BitCount() const { unsigned wordCount = WordCount(); if (wordCount) return (wordCount-1)*WORD_BITS + BitPrecision(reg[wordCount-1]); else return 0; } void Integer::Decode(const byte *input, size_t inputLen, Signedness s) { CRYPTOPP_ASSERT(input && inputLen); // NULL buffer StringStore store(input, inputLen); Decode(store, inputLen, s); } void Integer::Decode(BufferedTransformation &bt, size_t inputLen, Signedness s) { CRYPTOPP_ASSERT(bt.MaxRetrievable() >= inputLen); if (bt.MaxRetrievable() < inputLen) throw InvalidArgument("Integer: input length is too small"); byte b; bt.Peek(b); sign = ((s==SIGNED) && (b & 0x80)) ? NEGATIVE : POSITIVE; while (inputLen>0 && (sign==POSITIVE ? b==0 : b==0xff)) { bt.Skip(1); inputLen--; bt.Peek(b); } reg.CleanNew(RoundupSize(BytesToWords(inputLen))); for (size_t i=inputLen; i > 0; i--) { bt.Get(b); reg[(i-1)/WORD_SIZE] |= word(b) << ((i-1)%WORD_SIZE)*8; } if (sign == NEGATIVE) { for (size_t i=inputLen; i 0; i--) bt.Put(GetByte(i-1)); } else { // take two's complement of *this Integer temp = Integer::Power2(8*STDMAX((size_t)ByteCount(), outputLen)) + *this; temp.Encode(bt, outputLen, UNSIGNED); } } void Integer::DEREncode(BufferedTransformation &bt) const { DERGeneralEncoder enc(bt, INTEGER); Encode(enc, MinEncodedSize(SIGNED), SIGNED); enc.MessageEnd(); } void Integer::BERDecode(const byte *input, size_t len) { CRYPTOPP_ASSERT(input && len); // NULL buffer StringStore store(input, len); BERDecode(store); } void Integer::BERDecode(BufferedTransformation &bt) { BERGeneralDecoder dec(bt, INTEGER); if (!dec.IsDefiniteLength() || dec.MaxRetrievable() < dec.RemainingLength()) BERDecodeError(); Decode(dec, (size_t)dec.RemainingLength(), SIGNED); dec.MessageEnd(); } void Integer::DEREncodeAsOctetString(BufferedTransformation &bt, size_t length) const { DERGeneralEncoder enc(bt, OCTET_STRING); Encode(enc, length); enc.MessageEnd(); } void Integer::BERDecodeAsOctetString(BufferedTransformation &bt, size_t length) { BERGeneralDecoder dec(bt, OCTET_STRING); if (!dec.IsDefiniteLength() || dec.RemainingLength() != length) BERDecodeError(); Decode(dec, length); dec.MessageEnd(); } size_t Integer::OpenPGPEncode(byte *output, size_t bufferSize) const { CRYPTOPP_ASSERT(output && bufferSize); // NULL buffer CRYPTOPP_ASSERT(bufferSize >= MinEncodedSize()); // Undersized buffer ArraySink sink(output, bufferSize); return OpenPGPEncode(sink); } size_t Integer::OpenPGPEncode(BufferedTransformation &bt) const { word16 bitCount = word16(BitCount()); bt.PutWord16(bitCount); size_t byteCount = BitsToBytes(bitCount); Encode(bt, byteCount); return 2 + byteCount; } void Integer::OpenPGPDecode(const byte *input, size_t len) { CRYPTOPP_ASSERT(input && len); // NULL buffer StringStore store(input, len); OpenPGPDecode(store); } void Integer::OpenPGPDecode(BufferedTransformation &bt) { word16 bitCount; if (bt.GetWord16(bitCount) != 2 || bt.MaxRetrievable() < BitsToBytes(bitCount)) throw OpenPGPDecodeErr(); Decode(bt, BitsToBytes(bitCount)); } void Integer::Randomize(RandomNumberGenerator &rng, size_t nbits) { const size_t nbytes = nbits/8 + 1; SecByteBlock buf(nbytes); rng.GenerateBlock(buf, nbytes); if (nbytes) buf[0] = (byte)Crop(buf[0], nbits % 8); Decode(buf, nbytes, UNSIGNED); } void Integer::Randomize(RandomNumberGenerator &rng, const Integer &min, const Integer &max) { if (min > max) throw InvalidArgument("Integer: Min must be no greater than Max"); Integer range = max - min; const unsigned int nbits = range.BitCount(); do { Randomize(rng, nbits); } while (*this > range); *this += min; } bool Integer::Randomize(RandomNumberGenerator &rng, const Integer &min, const Integer &max, RandomNumberType rnType, const Integer &equiv, const Integer &mod) { return GenerateRandomNoThrow(rng, MakeParameters("Min", min)("Max", max)("RandomNumberType", rnType)("EquivalentTo", equiv)("Mod", mod)); } class KDF2_RNG : public RandomNumberGenerator { public: KDF2_RNG(const byte *seed, size_t seedSize) : m_counter(0), m_counterAndSeed(seedSize + 4) { memcpy(m_counterAndSeed + 4, seed, seedSize); } void GenerateBlock(byte *output, size_t size) { CRYPTOPP_ASSERT(output && size); // NULL buffer PutWord(false, BIG_ENDIAN_ORDER, m_counterAndSeed, m_counter); ++m_counter; P1363_KDF2::DeriveKey(output, size, m_counterAndSeed, m_counterAndSeed.size(), NULLPTR, 0); } private: word32 m_counter; SecByteBlock m_counterAndSeed; }; bool Integer::GenerateRandomNoThrow(RandomNumberGenerator &i_rng, const NameValuePairs ¶ms) { Integer min = params.GetValueWithDefault("Min", Integer::Zero()); Integer max; if (!params.GetValue("Max", max)) { int bitLength; if (params.GetIntValue("BitLength", bitLength)) max = Integer::Power2(bitLength); else throw InvalidArgument("Integer: missing Max argument"); } if (min > max) throw InvalidArgument("Integer: Min must be no greater than Max"); Integer equiv = params.GetValueWithDefault("EquivalentTo", Integer::Zero()); Integer mod = params.GetValueWithDefault("Mod", Integer::One()); if (equiv.IsNegative() || equiv >= mod) throw InvalidArgument("Integer: invalid EquivalentTo and/or Mod argument"); Integer::RandomNumberType rnType = params.GetValueWithDefault("RandomNumberType", Integer::ANY); member_ptr kdf2Rng; ConstByteArrayParameter seed; if (params.GetValue(Name::Seed(), seed)) { ByteQueue bq; DERSequenceEncoder seq(bq); min.DEREncode(seq); max.DEREncode(seq); equiv.DEREncode(seq); mod.DEREncode(seq); DEREncodeUnsigned(seq, rnType); DEREncodeOctetString(seq, seed.begin(), seed.size()); seq.MessageEnd(); SecByteBlock finalSeed((size_t)bq.MaxRetrievable()); bq.Get(finalSeed, finalSeed.size()); kdf2Rng.reset(new KDF2_RNG(finalSeed.begin(), finalSeed.size())); } RandomNumberGenerator &rng = kdf2Rng.get() ? (RandomNumberGenerator &)*kdf2Rng : i_rng; switch (rnType) { case ANY: if (mod == One()) Randomize(rng, min, max); else { Integer min1 = min + (equiv-min)%mod; if (max < min1) return false; Randomize(rng, Zero(), (max - min1) / mod); *this *= mod; *this += min1; } return true; case PRIME: { const PrimeSelector *pSelector = params.GetValueWithDefault(Name::PointerToPrimeSelector(), (const PrimeSelector *)NULLPTR); int i; i = 0; while (1) { if (++i==16) { // check if there are any suitable primes in [min, max] Integer first = min; if (FirstPrime(first, max, equiv, mod, pSelector)) { // if there is only one suitable prime, we're done *this = first; if (!FirstPrime(first, max, equiv, mod, pSelector)) return true; } else return false; } Randomize(rng, min, max); if (FirstPrime(*this, STDMIN(*this+mod*PrimeSearchInterval(max), max), equiv, mod, pSelector)) return true; } } default: throw InvalidArgument("Integer: invalid RandomNumberType argument"); } } std::istream& operator>>(std::istream& in, Integer &a) { char c; unsigned int length = 0; SecBlock str(length + 16); std::ws(in); do { in.read(&c, 1); str[length++] = c; if (length >= str.size()) str.Grow(length + 16); } while (in && (c=='-' || c=='x' || (c>='0' && c<='9') || (c>='a' && c<='f') || (c>='A' && c<='F') || c=='h' || c=='H' || c=='o' || c=='O' || c==',' || c=='.')); if (in.gcount()) in.putback(c); str[length-1] = '\0'; a = Integer(str); return in; } std::ostream& operator<<(std::ostream& out, const Integer &a) { // Get relevant conversion specifications from ostream. const long f = out.flags() & std::ios::basefield; // Get base digits. int base, block; char suffix; switch(f) { case std::ios::oct : base = 8; block = 8; suffix = 'o'; break; case std::ios::hex : base = 16; block = 4; suffix = 'h'; break; default : base = 10; block = 3; suffix = '.'; } Integer temp1=a, temp2; if (a.IsNegative()) { out << '-'; temp1.Negate(); } if (!a) out << '0'; static const char upper[]="0123456789ABCDEF"; static const char lower[]="0123456789abcdef"; const char* vec = (out.flags() & std::ios::uppercase) ? upper : lower; unsigned int i=0; SecBlock s(a.BitCount() / (SaturatingSubtract1(BitPrecision(base),1U)) + 1); while (!!temp1) { word digit; Integer::Divide(digit, temp2, temp1, base); s[i++]=vec[digit]; temp1.swap(temp2); } while (i--) { out << s[i]; // if (i && !(i%block)) // out << ","; } #ifdef CRYPTOPP_USE_STD_SHOWBASE if (out.flags() & std::ios_base::showbase) out << suffix; return out; #else return out << suffix; #endif } Integer& Integer::operator++() { if (NotNegative()) { if (Increment(reg, reg.size())) { reg.CleanGrow(2*reg.size()); reg[reg.size()/2]=1; } } else { word borrow = Decrement(reg, reg.size()); CRYPTOPP_ASSERT(!borrow); CRYPTOPP_UNUSED(borrow); if (WordCount()==0) *this = Zero(); } return *this; } Integer& Integer::operator--() { if (IsNegative()) { if (Increment(reg, reg.size())) { reg.CleanGrow(2*reg.size()); reg[reg.size()/2]=1; } } else { if (Decrement(reg, reg.size())) *this = -One(); } return *this; } // This is a bit operation. We set sign to POSITIVE, so there's no need to // worry about negative zero. Also see http://stackoverflow.com/q/11644362. Integer Integer::And(const Integer& t) const { if (this == &t) { return AbsoluteValue(); } else if (reg.size() >= t.reg.size()) { Integer result(t); AndWords(result.reg, reg, t.reg.size()); result.sign = POSITIVE; return result; } else // reg.size() < t.reg.size() { Integer result(*this); AndWords(result.reg, t.reg, reg.size()); result.sign = POSITIVE; return result; } } // This is a bit operation. We set sign to POSITIVE, so there's no need to // worry about negative zero. Also see http://stackoverflow.com/q/11644362. Integer Integer::Or(const Integer& t) const { if (this == &t) { return AbsoluteValue(); } else if (reg.size() >= t.reg.size()) { Integer result(*this); OrWords(result.reg, t.reg, t.reg.size()); result.sign = POSITIVE; return result; } else // reg.size() < t.reg.size() { Integer result(t); OrWords(result.reg, reg, reg.size()); result.sign = POSITIVE; return result; } } // This is a bit operation. We set sign to POSITIVE, so there's no need to // worry about negative zero. Also see http://stackoverflow.com/q/11644362. Integer Integer::Xor(const Integer& t) const { if (this == &t) { return Integer::Zero(); } else if (reg.size() >= t.reg.size()) { Integer result(*this); XorWords(result.reg, t.reg, t.reg.size()); result.sign = POSITIVE; return result; } else // reg.size() < t.reg.size() { Integer result(t); XorWords(result.reg, reg, reg.size()); result.sign = POSITIVE; return result; } } void PositiveAdd(Integer &sum, const Integer &a, const Integer& b) { // Profiling tells us the original second Else If was dominant, so it was promoted to the first If statement. // The code change occurred at Commit dc99266599a0e72d. int carry; const bool pre = (a.reg.size() == b.reg.size()); if (!pre && a.reg.size() > b.reg.size()) { carry = Add(sum.reg, a.reg, b.reg, b.reg.size()); CopyWords(sum.reg+b.reg.size(), a.reg+b.reg.size(), a.reg.size()-b.reg.size()); carry = Increment(sum.reg+b.reg.size(), a.reg.size()-b.reg.size(), carry); } else if (pre) { carry = Add(sum.reg, a.reg, b.reg, a.reg.size()); } else { carry = Add(sum.reg, a.reg, b.reg, a.reg.size()); CopyWords(sum.reg+a.reg.size(), b.reg+a.reg.size(), b.reg.size()-a.reg.size()); carry = Increment(sum.reg+a.reg.size(), b.reg.size()-a.reg.size(), carry); } if (carry) { sum.reg.CleanGrow(2*sum.reg.size()); sum.reg[sum.reg.size()/2] = 1; } sum.sign = Integer::POSITIVE; } void PositiveSubtract(Integer &diff, const Integer &a, const Integer& b) { unsigned aSize = a.WordCount(); aSize += aSize%2; unsigned bSize = b.WordCount(); bSize += bSize%2; // Profiling tells us the original second Else If was dominant, so it was promoted to the first If statement. // The code change occurred at Commit dc99266599a0e72d. if (aSize > bSize) { word borrow = Subtract(diff.reg, a.reg, b.reg, bSize); CopyWords(diff.reg+bSize, a.reg+bSize, aSize-bSize); borrow = Decrement(diff.reg+bSize, aSize-bSize, borrow); CRYPTOPP_ASSERT(!borrow); diff.sign = Integer::POSITIVE; } else if (aSize == bSize) { if (Compare(a.reg, b.reg, aSize) >= 0) { Subtract(diff.reg, a.reg, b.reg, aSize); diff.sign = Integer::POSITIVE; } else { Subtract(diff.reg, b.reg, a.reg, aSize); diff.sign = Integer::NEGATIVE; } } else { word borrow = Subtract(diff.reg, b.reg, a.reg, aSize); CopyWords(diff.reg+aSize, b.reg+aSize, bSize-aSize); borrow = Decrement(diff.reg+aSize, bSize-aSize, borrow); CRYPTOPP_ASSERT(!borrow); diff.sign = Integer::NEGATIVE; } } // MSVC .NET 2003 workaround template inline const T& STDMAX2(const T& a, const T& b) { return a < b ? b : a; } Integer Integer::Plus(const Integer& b) const { Integer sum((word)0, STDMAX2(reg.size(), b.reg.size())); if (NotNegative()) { if (b.NotNegative()) PositiveAdd(sum, *this, b); else PositiveSubtract(sum, *this, b); } else { if (b.NotNegative()) PositiveSubtract(sum, b, *this); else { PositiveAdd(sum, *this, b); sum.sign = Integer::NEGATIVE; } } return sum; } Integer& Integer::operator+=(const Integer& t) { reg.CleanGrow(t.reg.size()); if (NotNegative()) { if (t.NotNegative()) PositiveAdd(*this, *this, t); else PositiveSubtract(*this, *this, t); } else { if (t.NotNegative()) PositiveSubtract(*this, t, *this); else { PositiveAdd(*this, *this, t); sign = Integer::NEGATIVE; } } return *this; } Integer Integer::Minus(const Integer& b) const { Integer diff((word)0, STDMAX2(reg.size(), b.reg.size())); if (NotNegative()) { if (b.NotNegative()) PositiveSubtract(diff, *this, b); else PositiveAdd(diff, *this, b); } else { if (b.NotNegative()) { PositiveAdd(diff, *this, b); diff.sign = Integer::NEGATIVE; } else PositiveSubtract(diff, b, *this); } return diff; } Integer& Integer::operator-=(const Integer& t) { reg.CleanGrow(t.reg.size()); if (NotNegative()) { if (t.NotNegative()) PositiveSubtract(*this, *this, t); else PositiveAdd(*this, *this, t); } else { if (t.NotNegative()) { PositiveAdd(*this, *this, t); sign = Integer::NEGATIVE; } else PositiveSubtract(*this, t, *this); } return *this; } Integer& Integer::operator<<=(size_t n) { const size_t wordCount = WordCount(); const size_t shiftWords = n / WORD_BITS; const unsigned int shiftBits = (unsigned int)(n % WORD_BITS); reg.CleanGrow(RoundupSize(wordCount+BitsToWords(n))); ShiftWordsLeftByWords(reg, wordCount + shiftWords, shiftWords); ShiftWordsLeftByBits(reg+shiftWords, wordCount+BitsToWords(shiftBits), shiftBits); return *this; } Integer& Integer::operator>>=(size_t n) { const size_t wordCount = WordCount(); const size_t shiftWords = n / WORD_BITS; const unsigned int shiftBits = (unsigned int)(n % WORD_BITS); ShiftWordsRightByWords(reg, wordCount, shiftWords); if (wordCount > shiftWords) ShiftWordsRightByBits(reg, wordCount-shiftWords, shiftBits); if (IsNegative() && WordCount()==0) // avoid -0 *this = Zero(); return *this; } Integer& Integer::operator&=(const Integer& t) { if (this != &t) { const size_t size = STDMIN(reg.size(), t.reg.size()); reg.resize(size); AndWords(reg, t.reg, size); } sign = POSITIVE; return *this; } Integer& Integer::operator|=(const Integer& t) { if (this != &t) { if (reg.size() >= t.reg.size()) { OrWords(reg, t.reg, t.reg.size()); } else // reg.size() < t.reg.size() { const size_t head = reg.size(); const size_t tail = t.reg.size() - reg.size(); reg.resize(head+tail); OrWords(reg, t.reg, head); CopyWords(reg+head,t.reg+head,tail); } } sign = POSITIVE; return *this; } Integer& Integer::operator^=(const Integer& t) { if (this == &t) { *this = Zero(); } else { if (reg.size() >= t.reg.size()) { XorWords(reg, t.reg, t.reg.size()); } else // reg.size() < t.reg.size() { const size_t head = reg.size(); const size_t tail = t.reg.size() - reg.size(); reg.resize(head+tail); XorWords(reg, t.reg, head); CopyWords(reg+head,t.reg+head,tail); } } sign = POSITIVE; return *this; } void PositiveMultiply(Integer &product, const Integer &a, const Integer &b) { size_t aSize = RoundupSize(a.WordCount()); size_t bSize = RoundupSize(b.WordCount()); product.reg.CleanNew(RoundupSize(aSize+bSize)); product.sign = Integer::POSITIVE; IntegerSecBlock workspace(aSize + bSize); AsymmetricMultiply(product.reg, workspace, a.reg, aSize, b.reg, bSize); } void Multiply(Integer &product, const Integer &a, const Integer &b) { PositiveMultiply(product, a, b); if (a.NotNegative() != b.NotNegative()) product.Negate(); } Integer Integer::Times(const Integer &b) const { Integer product; Multiply(product, *this, b); return product; } /* void PositiveDivide(Integer &remainder, Integer "ient, const Integer ÷nd, const Integer &divisor) { remainder.reg.CleanNew(divisor.reg.size()); remainder.sign = Integer::POSITIVE; quotient.reg.New(0); quotient.sign = Integer::POSITIVE; unsigned i=dividend.BitCount(); while (i--) { word overflow = ShiftWordsLeftByBits(remainder.reg, remainder.reg.size(), 1); remainder.reg[0] |= dividend[i]; if (overflow || remainder >= divisor) { Subtract(remainder.reg, remainder.reg, divisor.reg, remainder.reg.size()); quotient.SetBit(i); } } } */ void PositiveDivide(Integer &remainder, Integer "ient, const Integer &a, const Integer &b) { unsigned aSize = a.WordCount(); unsigned bSize = b.WordCount(); if (!bSize) throw Integer::DivideByZero(); if (aSize < bSize) { remainder = a; remainder.sign = Integer::POSITIVE; quotient = Integer::Zero(); return; } aSize += aSize%2; // round up to next even number bSize += bSize%2; remainder.reg.CleanNew(RoundupSize(bSize)); remainder.sign = Integer::POSITIVE; quotient.reg.CleanNew(RoundupSize(aSize-bSize+2)); quotient.sign = Integer::POSITIVE; IntegerSecBlock T(aSize+3*(bSize+2)); Divide(remainder.reg, quotient.reg, T, a.reg, aSize, b.reg, bSize); } void Integer::Divide(Integer &remainder, Integer "ient, const Integer ÷nd, const Integer &divisor) { PositiveDivide(remainder, quotient, dividend, divisor); if (dividend.IsNegative()) { quotient.Negate(); if (remainder.NotZero()) { --quotient; remainder = divisor.AbsoluteValue() - remainder; } } if (divisor.IsNegative()) quotient.Negate(); } void Integer::DivideByPowerOf2(Integer &r, Integer &q, const Integer &a, unsigned int n) { q = a; q >>= n; const size_t wordCount = BitsToWords(n); if (wordCount <= a.WordCount()) { r.reg.resize(RoundupSize(wordCount)); CopyWords(r.reg, a.reg, wordCount); SetWords(r.reg+wordCount, 0, r.reg.size()-wordCount); if (n % WORD_BITS != 0) r.reg[wordCount-1] %= (word(1) << (n % WORD_BITS)); } else { r.reg.resize(RoundupSize(a.WordCount())); CopyWords(r.reg, a.reg, r.reg.size()); } r.sign = POSITIVE; if (a.IsNegative() && r.NotZero()) { --q; r = Power2(n) - r; } } Integer Integer::DividedBy(const Integer &b) const { Integer remainder, quotient; Integer::Divide(remainder, quotient, *this, b); return quotient; } Integer Integer::Modulo(const Integer &b) const { Integer remainder, quotient; Integer::Divide(remainder, quotient, *this, b); return remainder; } void Integer::Divide(word &remainder, Integer "ient, const Integer ÷nd, word divisor) { if (!divisor) throw Integer::DivideByZero(); if ((divisor & (divisor-1)) == 0) // divisor is a power of 2 { quotient = dividend >> (BitPrecision(divisor)-1); remainder = dividend.reg[0] & (divisor-1); return; } unsigned int i = dividend.WordCount(); quotient.reg.CleanNew(RoundupSize(i)); remainder = 0; while (i--) { quotient.reg[i] = DWord(dividend.reg[i], remainder) / divisor; remainder = DWord(dividend.reg[i], remainder) % divisor; } if (dividend.NotNegative()) quotient.sign = POSITIVE; else { quotient.sign = NEGATIVE; if (remainder) { --quotient; remainder = divisor - remainder; } } } Integer Integer::DividedBy(word b) const { word remainder; Integer quotient; Integer::Divide(remainder, quotient, *this, b); return quotient; } word Integer::Modulo(word divisor) const { if (!divisor) throw Integer::DivideByZero(); word remainder; // Profiling tells us the original Else was dominant, so it was promoted to the first If statement. // The code change occurred at Commit dc99266599a0e72d. if ((divisor & (divisor-1)) != 0) // divisor is not a power of 2 { // Profiling tells us the original Else was dominant, so it was promoted to the first If statement. // The code change occurred at Commit dc99266599a0e72d. unsigned int i = WordCount(); if (divisor > 5) { remainder = 0; while (i--) remainder = DWord(reg[i], remainder) % divisor; } else { DWord sum(0, 0); while (i--) sum += reg[i]; remainder = sum % divisor; } } else // divisor is a power of 2 { remainder = reg[0] & (divisor-1); } if (IsNegative() && remainder) remainder = divisor - remainder; return remainder; } void Integer::Negate() { if (!!(*this)) // don't flip sign if *this==0 sign = Sign(1-sign); } int Integer::PositiveCompare(const Integer& t) const { // Profiling tells us the original Else was dominant, so it was promoted to the first If statement. // The code change occurred at Commit dc99266599a0e72d. const unsigned size = WordCount(), tSize = t.WordCount(); if (size != tSize) return size > tSize ? 1 : -1; else return CryptoPP::Compare(reg, t.reg, size); } int Integer::Compare(const Integer& t) const { if (NotNegative()) { if (t.NotNegative()) return PositiveCompare(t); else return 1; } else { if (t.NotNegative()) return -1; else return -PositiveCompare(t); } } Integer Integer::SquareRoot() const { if (!IsPositive()) return Zero(); // overestimate square root Integer x, y = Power2((BitCount()+1)/2); CRYPTOPP_ASSERT(y*y >= *this); do { x = y; y = (x + *this/x) >> 1; } while (y().Gcd(a, b); } Integer Integer::InverseMod(const Integer &m) const { CRYPTOPP_ASSERT(m.NotNegative()); if (IsNegative()) return Modulo(m).InverseMod(m); if (m.IsEven()) { if (!m || IsEven()) return Zero(); // no inverse if (*this == One()) return One(); Integer u = m.Modulo(*this).InverseMod(*this); return !u ? Zero() : (m*(*this-u)+1)/(*this); } SecBlock T(m.reg.size() * 4); Integer r((word)0, m.reg.size()); unsigned k = AlmostInverse(r.reg, T, reg, reg.size(), m.reg, m.reg.size()); DivideByPower2Mod(r.reg, r.reg, k, m.reg, m.reg.size()); return r; } word Integer::InverseMod(word mod) const { word g0 = mod, g1 = *this % mod; word v0 = 0, v1 = 1; word y; while (g1) { if (g1 == 1) return v1; y = g0 / g1; g0 = g0 % g1; v0 += y * v1; if (!g0) break; if (g0 == 1) return mod-v0; y = g1 / g0; g1 = g1 % g0; v1 += y * v0; } return 0; } // ******************************************************** ModularArithmetic::ModularArithmetic(BufferedTransformation &bt) { BERSequenceDecoder seq(bt); OID oid(seq); if (oid != ASN1::prime_field()) BERDecodeError(); m_modulus.BERDecode(seq); seq.MessageEnd(); m_result.reg.resize(m_modulus.reg.size()); } void ModularArithmetic::DEREncode(BufferedTransformation &bt) const { DERSequenceEncoder seq(bt); ASN1::prime_field().DEREncode(seq); m_modulus.DEREncode(seq); seq.MessageEnd(); } void ModularArithmetic::DEREncodeElement(BufferedTransformation &out, const Element &a) const { a.DEREncodeAsOctetString(out, MaxElementByteLength()); } void ModularArithmetic::BERDecodeElement(BufferedTransformation &in, Element &a) const { a.BERDecodeAsOctetString(in, MaxElementByteLength()); } const Integer& ModularArithmetic::Half(const Integer &a) const { if (a.reg.size()==m_modulus.reg.size()) { CryptoPP::DivideByPower2Mod(m_result.reg.begin(), a.reg, 1, m_modulus.reg, a.reg.size()); return m_result; } else return m_result1 = (a.IsEven() ? (a >> 1) : ((a+m_modulus) >> 1)); } const Integer& ModularArithmetic::Add(const Integer &a, const Integer &b) const { if (a.reg.size()==m_modulus.reg.size() && b.reg.size()==m_modulus.reg.size()) { if (CryptoPP::Add(m_result.reg.begin(), a.reg, b.reg, a.reg.size()) || Compare(m_result.reg, m_modulus.reg, a.reg.size()) >= 0) { CryptoPP::Subtract(m_result.reg.begin(), m_result.reg, m_modulus.reg, a.reg.size()); } return m_result; } else { m_result1 = a+b; if (m_result1 >= m_modulus) m_result1 -= m_modulus; return m_result1; } } Integer& ModularArithmetic::Accumulate(Integer &a, const Integer &b) const { if (a.reg.size()==m_modulus.reg.size() && b.reg.size()==m_modulus.reg.size()) { if (CryptoPP::Add(a.reg, a.reg, b.reg, a.reg.size()) || Compare(a.reg, m_modulus.reg, a.reg.size()) >= 0) { CryptoPP::Subtract(a.reg, a.reg, m_modulus.reg, a.reg.size()); } } else { a+=b; if (a>=m_modulus) a-=m_modulus; } return a; } const Integer& ModularArithmetic::Subtract(const Integer &a, const Integer &b) const { if (a.reg.size()==m_modulus.reg.size() && b.reg.size()==m_modulus.reg.size()) { if (CryptoPP::Subtract(m_result.reg.begin(), a.reg, b.reg, a.reg.size())) CryptoPP::Add(m_result.reg.begin(), m_result.reg, m_modulus.reg, a.reg.size()); return m_result; } else { m_result1 = a-b; if (m_result1.IsNegative()) m_result1 += m_modulus; return m_result1; } } Integer& ModularArithmetic::Reduce(Integer &a, const Integer &b) const { if (a.reg.size()==m_modulus.reg.size() && b.reg.size()==m_modulus.reg.size()) { if (CryptoPP::Subtract(a.reg, a.reg, b.reg, a.reg.size())) CryptoPP::Add(a.reg, a.reg, m_modulus.reg, a.reg.size()); } else { a-=b; if (a.IsNegative()) a+=m_modulus; } return a; } const Integer& ModularArithmetic::Inverse(const Integer &a) const { if (!a) return a; CopyWords(m_result.reg.begin(), m_modulus.reg, m_modulus.reg.size()); if (CryptoPP::Subtract(m_result.reg.begin(), m_result.reg, a.reg, a.reg.size())) Decrement(m_result.reg.begin()+a.reg.size(), m_modulus.reg.size()-a.reg.size()); return m_result; } Integer ModularArithmetic::CascadeExponentiate(const Integer &x, const Integer &e1, const Integer &y, const Integer &e2) const { if (m_modulus.IsOdd()) { MontgomeryRepresentation dr(m_modulus); return dr.ConvertOut(dr.CascadeExponentiate(dr.ConvertIn(x), e1, dr.ConvertIn(y), e2)); } else return AbstractRing::CascadeExponentiate(x, e1, y, e2); } void ModularArithmetic::SimultaneousExponentiate(Integer *results, const Integer &base, const Integer *exponents, unsigned int exponentsCount) const { if (m_modulus.IsOdd()) { MontgomeryRepresentation dr(m_modulus); dr.SimultaneousExponentiate(results, dr.ConvertIn(base), exponents, exponentsCount); for (unsigned int i=0; i::SimultaneousExponentiate(results, base, exponents, exponentsCount); } MontgomeryRepresentation::MontgomeryRepresentation(const Integer &m) // modulus must be odd : ModularArithmetic(m), m_u((word)0, m_modulus.reg.size()), m_workspace(5*m_modulus.reg.size()) { if (!m_modulus.IsOdd()) throw InvalidArgument("MontgomeryRepresentation: Montgomery representation requires an odd modulus"); RecursiveInverseModPower2(m_u.reg, m_workspace, m_modulus.reg, m_modulus.reg.size()); } const Integer& MontgomeryRepresentation::Multiply(const Integer &a, const Integer &b) const { word *const T = m_workspace.begin(); word *const R = m_result.reg.begin(); const size_t N = m_modulus.reg.size(); CRYPTOPP_ASSERT(a.reg.size()<=N && b.reg.size()<=N); AsymmetricMultiply(T, T+2*N, a.reg, a.reg.size(), b.reg, b.reg.size()); SetWords(T+a.reg.size()+b.reg.size(), 0, 2*N-a.reg.size()-b.reg.size()); MontgomeryReduce(R, T+2*N, T, m_modulus.reg, m_u.reg, N); return m_result; } const Integer& MontgomeryRepresentation::Square(const Integer &a) const { word *const T = m_workspace.begin(); word *const R = m_result.reg.begin(); const size_t N = m_modulus.reg.size(); CRYPTOPP_ASSERT(a.reg.size()<=N); CryptoPP::Square(T, T+2*N, a.reg, a.reg.size()); SetWords(T+2*a.reg.size(), 0, 2*N-2*a.reg.size()); MontgomeryReduce(R, T+2*N, T, m_modulus.reg, m_u.reg, N); return m_result; } Integer MontgomeryRepresentation::ConvertOut(const Integer &a) const { word *const T = m_workspace.begin(); word *const R = m_result.reg.begin(); const size_t N = m_modulus.reg.size(); CRYPTOPP_ASSERT(a.reg.size()<=N); CopyWords(T, a.reg, a.reg.size()); SetWords(T+a.reg.size(), 0, 2*N-a.reg.size()); MontgomeryReduce(R, T+2*N, T, m_modulus.reg, m_u.reg, N); return m_result; } const Integer& MontgomeryRepresentation::MultiplicativeInverse(const Integer &a) const { // return (EuclideanMultiplicativeInverse(a, modulus)<<(2*WORD_BITS*modulus.reg.size()))%modulus; word *const T = m_workspace.begin(); word *const R = m_result.reg.begin(); const size_t N = m_modulus.reg.size(); CRYPTOPP_ASSERT(a.reg.size()<=N); CopyWords(T, a.reg, a.reg.size()); SetWords(T+a.reg.size(), 0, 2*N-a.reg.size()); MontgomeryReduce(R, T+2*N, T, m_modulus.reg, m_u.reg, N); unsigned k = AlmostInverse(R, T, R, N, m_modulus.reg, N); // cout << "k=" << k << " N*32=" << 32*N << endl; if (k>N*WORD_BITS) DivideByPower2Mod(R, R, k-N*WORD_BITS, m_modulus.reg, N); else MultiplyByPower2Mod(R, R, N*WORD_BITS-k, m_modulus.reg, N); return m_result; } // Specialization declared in misc.h to allow us to print integers // with additional control options, like arbirary bases and uppercase. template <> CRYPTOPP_DLL std::string IntToString(Integer value, unsigned int base) { // Hack... set the high bit for uppercase. Set the next bit fo a suffix. static const unsigned int BIT_32 = (1U << 31); const bool UPPER = !!(base & BIT_32); static const unsigned int BIT_31 = (1U << 30); const bool BASE = !!(base & BIT_31); const char CH = UPPER ? 'A' : 'a'; base &= ~(BIT_32|BIT_31); CRYPTOPP_ASSERT(base >= 2 && base <= 32); if (value == 0) return "0"; bool negative = false, zero = false; if (value.IsNegative()) { negative = true; value.Negate(); } if (!value) zero = true; SecBlock s(value.BitCount() / (SaturatingSubtract1(BitPrecision(base),1U)) + 1); Integer temp; unsigned int i=0; while (!!value) { word digit; Integer::Divide(digit, temp, value, word(base)); s[i++]=char((digit < 10 ? '0' : (CH - 10)) + digit); value.swap(temp); } std::string result; result.reserve(i+2); if (negative) result += '-'; if (zero) result += '0'; while (i--) result += s[i]; if (BASE) { if (base == 10) result += '.'; else if (base == 16) result += 'h'; else if (base == 8) result += 'o'; else if (base == 2) result += 'b'; } return result; } // Specialization declared in misc.h to avoid Coverity findings. template <> CRYPTOPP_DLL std::string IntToString(word64 value, unsigned int base) { // Hack... set the high bit for uppercase. static const unsigned int HIGH_BIT = (1U << 31); const char CH = !!(base & HIGH_BIT) ? 'A' : 'a'; base &= ~HIGH_BIT; CRYPTOPP_ASSERT(base >= 2); if (value == 0) return "0"; std::string result; while (value > 0) { word64 digit = value % base; result = char((digit < 10 ? '0' : (CH - 10)) + digit) + result; value /= base; } return result; } #ifndef CRYPTOPP_NO_ASSIGN_TO_INTEGER // Allow the linker to discard Integer code if not needed. // Also see http://github.com/weidai11/cryptopp/issues/389. bool AssignIntToInteger(const std::type_info &valueType, void *pInteger, const void *pInt) { if (valueType != typeid(Integer)) return false; *reinterpret_cast(pInteger) = *reinterpret_cast(pInt); return true; } #endif NAMESPACE_END #endif