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2765 lines
99 KiB
C++
2765 lines
99 KiB
C++
// ppc_simd.h - written and placed in public domain by Jeffrey Walton
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/// \file ppc_simd.h
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/// \brief Support functions for PowerPC and vector operations
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/// \details This header provides an agnostic interface into Clang, GCC
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/// and IBM XL C/C++ compilers modulo their different built-in functions
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/// for accessing vector instructions.
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/// \details The abstractions are necessary to support back to GCC 4.8 and
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/// XLC 11 and 12. GCC 4.8 and 4.9 are still popular, and they are the
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/// default compiler for GCC112, GCC119 and others on the compile farm.
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/// Older IBM XL C/C++ compilers also have the need due to lack of
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/// <tt>vec_xl</tt> and <tt>vec_xst</tt> support on some platforms. Modern
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/// compilers provide best support and don't need many of the hacks
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/// below.
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/// \details The library is tested with the following PowerPC machines and
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/// compilers. GCC110, GCC111, GCC112, GCC119 and GCC135 are provided by
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/// the <A HREF="https://cfarm.tetaneutral.net/">GCC Compile Farm</A>
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/// - PowerMac G5, OSX 10.5, POWER4, Apple GCC 4.0
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/// - PowerMac G5, OSX 10.5, POWER4, Macports GCC 5.0
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/// - GCC110, Linux, POWER7, GCC 4.8.5
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/// - GCC110, Linux, POWER7, XLC 12.01
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/// - GCC111, AIX, POWER7, GCC 4.8.1
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/// - GCC111, AIX, POWER7, XLC 12.01
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/// - GCC112, Linux, POWER8, GCC 4.8.5
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/// - GCC112, Linux, POWER8, XLC 13.01
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/// - GCC112, Linux, POWER8, Clang 7.0
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/// - GCC119, AIX, POWER8, GCC 7.2.0
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/// - GCC119, AIX, POWER8, XLC 13.01
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/// - GCC135, Linux, POWER9, GCC 7.0
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/// \details 12 machines are used for testing because the three compilers form
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/// five or six profiles. The profiles are listed below.
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/// - GCC (Linux GCC, Macports GCC, etc. Consistent across machines)
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/// - XLC 13.0 and earlier (all IBM components)
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/// - XLC 13.1 and later on Linux (LLVM front-end, no compatibility macros)
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/// - XLC 13.1 and later on Linux (LLVM front-end, -qxlcompatmacros option)
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/// - early LLVM Clang (traditional Clang compiler)
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/// - late LLVM Clang (traditional Clang compiler)
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/// \details The LLVM front-end makes it tricky to write portable code because
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/// LLVM pretends to be other compilers but cannot consume other compiler's
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/// builtins. When using XLC with -qxlcompatmacros the compiler pretends to
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/// be GCC, Clang and XLC all at once but it can only consume it's variety
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/// of builtins.
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/// \details At Crypto++ 8.0 the various <tt>Vector{FuncName}</tt> were
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/// renamed to <tt>Vec{FuncName}</tt>. For example, <tt>VectorAnd</tt> was
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/// changed to <tt>VecAnd</tt>. The name change helped consolidate two
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/// slightly different implementations.
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/// \details At Crypto++ 8.3 the library added select 64-bit functions for
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/// 32-bit Altivec. For example, <tt>VecAdd64</tt> and <tt>VecSub64</tt>
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/// take 32-bit vectors and adds or subtracts them as if there were vectors
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/// with two 64-bit elements. The functions dramtically improve performance
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/// for some algorithms on some platforms, like SIMON128 and SPECK128 on
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/// Power6 and earlier. For example, SPECK128 improved from 70 cpb to
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/// 10 cpb on an old PowerMac. Use the functions like shown below.
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/// <pre>
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/// \#if defined(_ARCH_PWR8)
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/// \# define speck128_t uint64x2_p
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/// \#else
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/// \# define speck128_t uint32x4_p
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/// \#endif
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///
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/// speck128_t rk, x1, x2, y1, y2;
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/// rk = (speck128_t)VecLoadAligned(ptr);
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/// x1 = VecRotateRight64<8>(x1);
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/// x1 = VecAdd64(x1, y1);
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/// ...</pre>
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/// \since Crypto++ 6.0, LLVM Clang compiler support since Crypto++ 8.0
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// Use __ALTIVEC__, _ARCH_PWR7, __VSX__, and _ARCH_PWR8 when detecting
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// actual availaibility of the feature for the source file being compiled.
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// The preprocessor macros depend on compiler options like -maltivec; and
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// not compiler versions.
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// For GCC see https://gcc.gnu.org/onlinedocs/gcc/Basic-PowerPC-Built-in-Functions.html
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// For XLC see the Compiler Reference manual. For Clang you have to experiment.
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// Clang does not document the compiler options, does not reject options it does
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// not understand, and pretends to be other compilers even though it cannot
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// process the builtins and intrinsics. Clang will waste hours of your time.
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// DO NOT USE this pattern in VecLoad and VecStore. We have to use the
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// code paths guarded by preprocessor macros because XLC 12 generates
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// bad code in some places. To verify the bad code generation test on
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// GCC111 with XLC 12.01 installed. XLC 13.01 on GCC112 and GCC119 are OK.
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//
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// inline uint32x4_p VecLoad(const byte src[16])
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// {
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// #if defined(__VSX__) || defined(_ARCH_PWR8)
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// return (uint32x4_p) *(uint8x16_p*)((byte*)src);
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// #else
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// return VecLoad_ALTIVEC(src);
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// #endif
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// }
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// We should be able to perform the load using inline asm on Power7 with
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// VSX or Power8. The inline asm will avoid C undefined behavior due to
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// casting from byte* to word32*. We are safe because our byte* are
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// 16-byte aligned for Altivec. Below is the big endian load. Little
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// endian would need to follow with xxpermdi for the reversal.
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//
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// __asm__ ("lxvw4x %x0, %1, %2" : "=wa"(v) : "r"(0), "r"(src) : );
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// GCC and XLC use integer math for the address (D-form or byte-offset
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// in the ISA manual). LLVM uses pointer math for the address (DS-form
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// or indexed in the ISA manual). To keep them consistent we calculate
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// the address from the offset and pass to a load or store function
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// using a 0 offset.
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#ifndef CRYPTOPP_PPC_CRYPTO_H
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#define CRYPTOPP_PPC_CRYPTO_H
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#include "config.h"
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#include "misc.h"
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#if defined(__ALTIVEC__)
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# include <altivec.h>
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# undef vector
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# undef pixel
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# undef bool
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#endif
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// XL C++ on AIX does not define VSX and does not
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// provide an option to set it. We have to set it
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// for the code below. This define must stay in
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// sync with the define in test_ppc_power7.cpp.
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#ifndef CRYPTOPP_DISABLE_POWER7
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# if defined(_AIX) && defined(_ARCH_PWR7) && defined(__xlC__)
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# define __VSX__ 1
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# endif
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#endif
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// XL C++ on AIX does not define CRYPTO and does not
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// provide an option to set it. We have to set it
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// for the code below. This define must stay in
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// sync with the define in test_ppc_power8.cpp
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#ifndef CRYPTOPP_DISABLE_POWER8
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# if defined(_AIX) && defined(_ARCH_PWR8) && defined(__xlC__)
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# define __CRYPTO__ 1
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# endif
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#endif
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/// \brief Cast array to vector pointer
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/// \details CONST_V8_CAST casts a const array to a vector
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/// pointer for a byte array. The Power ABI says source arrays
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/// are non-const, so this define removes the const. XLC++ will
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/// fail the compile if the source array is const.
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#define CONST_V8_CAST(x) ((unsigned char*)(x))
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/// \brief Cast array to vector pointer
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/// \details CONST_V32_CAST casts a const array to a vector
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/// pointer for a word array. The Power ABI says source arrays
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/// are non-const, so this define removes the const. XLC++ will
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/// fail the compile if the source array is const.
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#define CONST_V32_CAST(x) ((unsigned int*)(x))
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/// \brief Cast array to vector pointer
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/// \details CONST_V64_CAST casts a const array to a vector
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/// pointer for a double word array. The Power ABI says source arrays
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/// are non-const, so this define removes the const. XLC++ will
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/// fail the compile if the source array is const.
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#define CONST_V64_CAST(x) ((unsigned long long*)(x))
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/// \brief Cast array to vector pointer
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/// \details NCONST_V8_CAST casts an array to a vector
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/// pointer for a byte array. The Power ABI says source arrays
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/// are non-const, so this define removes the const. XLC++ will
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/// fail the compile if the source array is const.
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#define NCONST_V8_CAST(x) ((unsigned char*)(x))
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/// \brief Cast array to vector pointer
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/// \details NCONST_V32_CAST casts an array to a vector
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/// pointer for a word array. The Power ABI says source arrays
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/// are non-const, so this define removes the const. XLC++ will
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/// fail the compile if the source array is const.
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#define NCONST_V32_CAST(x) ((unsigned int*)(x))
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/// \brief Cast array to vector pointer
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/// \details NCONST_V64_CAST casts an array to a vector
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/// pointer for a double word array. The Power ABI says source arrays
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/// are non-const, so this define removes the const. XLC++ will
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/// fail the compile if the source array is const.
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#define NCONST_V64_CAST(x) ((unsigned long long*)(x))
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// VecLoad_ALTIVEC and VecStore_ALTIVEC are
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// too noisy on modern compilers
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#if CRYPTOPP_GCC_DIAGNOSTIC_AVAILABLE
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# pragma GCC diagnostic push
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# pragma GCC diagnostic ignored "-Wdeprecated"
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#endif
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NAMESPACE_BEGIN(CryptoPP)
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#if defined(__ALTIVEC__) || defined(CRYPTOPP_DOXYGEN_PROCESSING)
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/// \brief Vector of 8-bit elements
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/// \par Wraps
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/// __vector unsigned char
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/// \since Crypto++ 6.0
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typedef __vector unsigned char uint8x16_p;
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/// \brief Vector of 16-bit elements
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/// \par Wraps
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/// __vector unsigned short
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/// \since Crypto++ 6.0
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typedef __vector unsigned short uint16x8_p;
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/// \brief Vector of 32-bit elements
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/// \par Wraps
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/// __vector unsigned int
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/// \since Crypto++ 6.0
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typedef __vector unsigned int uint32x4_p;
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#if defined(__VSX__) || defined(_ARCH_PWR8) || defined(CRYPTOPP_DOXYGEN_PROCESSING)
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/// \brief Vector of 64-bit elements
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/// \details uint64x2_p is available on POWER7 with VSX and above. Most
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/// supporting functions, like 64-bit <tt>vec_add</tt> (<tt>vaddudm</tt>)
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/// and <tt>vec_sub</tt> (<tt>vsubudm</tt>), did not arrive until POWER8.
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/// \par Wraps
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/// __vector unsigned long long
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/// \since Crypto++ 6.0
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typedef __vector unsigned long long uint64x2_p;
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#endif // VSX or ARCH_PWR8
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/// \brief The 0 vector
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/// \return a 32-bit vector of 0's
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/// \since Crypto++ 8.0
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inline uint32x4_p VecZero()
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{
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const uint32x4_p v = {0,0,0,0};
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return v;
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}
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/// \brief The 1 vector
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/// \return a 32-bit vector of 1's
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/// \since Crypto++ 8.0
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inline uint32x4_p VecOne()
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{
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const uint32x4_p v = {1,1,1,1};
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return v;
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}
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/// \brief Reverse bytes in a vector
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/// \tparam T vector type
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/// \param data the vector
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/// \return vector
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/// \details VecReverse() reverses the bytes in a vector
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/// \par Wraps
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/// vec_perm
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/// \since Crypto++ 6.0
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template <class T>
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inline T VecReverse(const T data)
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{
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#if defined(CRYPTOPP_BIG_ENDIAN)
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const uint8x16_p mask = {15,14,13,12, 11,10,9,8, 7,6,5,4, 3,2,1,0};
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return (T)vec_perm(data, data, mask);
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#else
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const uint8x16_p mask = {0,1,2,3, 4,5,6,7, 8,9,10,11, 12,13,14,15};
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return (T)vec_perm(data, data, mask);
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#endif
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}
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/// \brief Reverse bytes in a vector
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/// \tparam T vector type
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/// \param data the vector
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/// \return vector
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/// \details VecReverseLE() reverses the bytes in a vector on
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/// little-endian systems.
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/// \par Wraps
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/// vec_perm
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/// \since Crypto++ 6.0
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template <class T>
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inline T VecReverseLE(const T data)
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{
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#if defined(CRYPTOPP_LITTLE_ENDIAN)
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const uint8x16_p mask = {15,14,13,12, 11,10,9,8, 7,6,5,4, 3,2,1,0};
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return (T)vec_perm(data, data, mask);
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#else
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return data;
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#endif
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}
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/// \brief Reverse bytes in a vector
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/// \tparam T vector type
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/// \param data the vector
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/// \return vector
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/// \details VecReverseBE() reverses the bytes in a vector on
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/// big-endian systems.
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/// \par Wraps
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/// vec_perm
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/// \since Crypto++ 6.0
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template <class T>
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inline T VecReverseBE(const T data)
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{
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#if defined(CRYPTOPP_BIG_ENDIAN)
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const uint8x16_p mask = {15,14,13,12, 11,10,9,8, 7,6,5,4, 3,2,1,0};
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return (T)vec_perm(data, data, mask);
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#else
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return data;
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#endif
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}
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/// \name LOAD OPERATIONS
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//@{
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/// \brief Loads a vector from a byte array
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/// \param src the byte array
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/// \details Loads a vector in native endian format from a byte array.
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/// \details VecLoad_ALTIVEC() uses <tt>vec_ld</tt> if the effective address
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/// of <tt>src</tt> is aligned. If unaligned it uses <tt>vec_lvsl</tt>,
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/// <tt>vec_ld</tt>, <tt>vec_perm</tt> and <tt>src</tt>. The fixups using
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/// <tt>vec_lvsl</tt> and <tt>vec_perm</tt> are relatively expensive so
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/// you should provide aligned memory addresses.
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/// \par Wraps
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/// vec_ld, vec_lvsl, vec_perm
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/// \sa VecLoad, VecLoadAligned
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/// \since Crypto++ 6.0
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inline uint32x4_p VecLoad_ALTIVEC(const byte src[16])
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{
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// Avoid IsAlignedOn for convenience.
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const uintptr_t addr = reinterpret_cast<uintptr_t>(src);
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if (addr % 16 == 0)
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{
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return (uint32x4_p)vec_ld(0, CONST_V8_CAST(addr));
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}
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else
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{
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// http://www.nxp.com/docs/en/reference-manual/ALTIVECPEM.pdf
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const uint8x16_p perm = vec_lvsl(0, CONST_V8_CAST(addr));
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const uint8x16_p low = vec_ld(0, CONST_V8_CAST(addr));
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const uint8x16_p high = vec_ld(15, CONST_V8_CAST(addr));
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return (uint32x4_p)vec_perm(low, high, perm);
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}
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}
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/// \brief Loads a vector from a byte array
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/// \param src the byte array
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/// \param off offset into the src byte array
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/// \details Loads a vector in native endian format from a byte array.
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/// \details VecLoad_ALTIVEC() uses <tt>vec_ld</tt> if the effective address
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/// of <tt>src</tt> is aligned. If unaligned it uses <tt>vec_lvsl</tt>,
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/// <tt>vec_ld</tt>, <tt>vec_perm</tt> and <tt>src</tt>.
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/// \details The fixups using <tt>vec_lvsl</tt> and <tt>vec_perm</tt> are
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/// relatively expensive so you should provide aligned memory addresses.
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/// \par Wraps
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/// vec_ld, vec_lvsl, vec_perm
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/// \sa VecLoad, VecLoadAligned
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/// \since Crypto++ 6.0
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inline uint32x4_p VecLoad_ALTIVEC(int off, const byte src[16])
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{
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// Avoid IsAlignedOn for convenience.
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const uintptr_t addr = reinterpret_cast<uintptr_t>(src)+off;
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if (addr % 16 == 0)
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{
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return (uint32x4_p)vec_ld(0, CONST_V8_CAST(addr));
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}
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else
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{
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// http://www.nxp.com/docs/en/reference-manual/ALTIVECPEM.pdf
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const uint8x16_p perm = vec_lvsl(0, CONST_V8_CAST(addr));
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const uint8x16_p low = vec_ld(0, CONST_V8_CAST(addr));
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const uint8x16_p high = vec_ld(15, CONST_V8_CAST(addr));
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return (uint32x4_p)vec_perm(low, high, perm);
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}
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}
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/// \brief Loads a vector from a byte array
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/// \param src the byte array
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/// \details VecLoad() loads a vector from a byte array.
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/// \details VecLoad() uses POWER9's <tt>vec_xl</tt> if available.
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/// The instruction does not require aligned effective memory addresses.
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/// VecLoad_ALTIVEC() is used if POWER9 is not available.
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/// VecLoad_ALTIVEC() can be relatively expensive if extra instructions
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/// are required to fix up unaligned memory addresses.
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/// \par Wraps
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/// vec_xl on POWER9 and above, Altivec load on POWER8 and below
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/// \sa VecLoad_ALTIVEC, VecLoadAligned
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/// \since Crypto++ 6.0
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inline uint32x4_p VecLoad(const byte src[16])
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{
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// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
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// word pointers. The ISA lacks loads for short* and char*.
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// Power9/ISA 3.0 provides vec_xl for all datatypes.
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const uintptr_t addr = reinterpret_cast<uintptr_t>(src);
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CRYPTOPP_ASSERT(addr % GetAlignmentOf<byte>() == 0);
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CRYPTOPP_UNUSED(addr);
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#if defined(_ARCH_PWR9)
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return (uint32x4_p)vec_xl(0, CONST_V8_CAST(src));
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#else
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return (uint32x4_p)VecLoad_ALTIVEC(CONST_V8_CAST(addr));
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#endif
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}
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/// \brief Loads a vector from a byte array
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/// \param src the byte array
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/// \param off offset into the src byte array
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/// \details VecLoad() loads a vector from a byte array.
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/// \details VecLoad() uses POWER9's <tt>vec_xl</tt> if available.
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/// The instruction does not require aligned effective memory addresses.
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/// VecLoad_ALTIVEC() is used if POWER9 is not available.
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/// VecLoad_ALTIVEC() can be relatively expensive if extra instructions
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/// are required to fix up unaligned memory addresses.
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/// \par Wraps
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/// vec_xl on POWER9 and above, Altivec load on POWER8 and below
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/// \sa VecLoad_ALTIVEC, VecLoadAligned
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/// \since Crypto++ 6.0
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inline uint32x4_p VecLoad(int off, const byte src[16])
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{
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// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
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// word pointers. The ISA lacks loads for short* and char*.
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// Power9/ISA 3.0 provides vec_xl for all datatypes.
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const uintptr_t addr = reinterpret_cast<uintptr_t>(src)+off;
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CRYPTOPP_ASSERT(addr % GetAlignmentOf<byte>() == 0);
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CRYPTOPP_UNUSED(addr);
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#if defined(_ARCH_PWR9)
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return (uint32x4_p)vec_xl(off, CONST_V8_CAST(src));
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#else
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return (uint32x4_p)VecLoad_ALTIVEC(CONST_V8_CAST(addr));
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#endif
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}
|
|
|
|
/// \brief Loads a vector from a word array
|
|
/// \param src the word array
|
|
/// \details VecLoad() loads a vector from a word array.
|
|
/// \details VecLoad() uses POWER7's and VSX's <tt>vec_xl</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecLoad_ALTIVEC() is used if POWER7 is not available.
|
|
/// VecLoad_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \par Wraps
|
|
/// vec_xl on VSX or POWER8 and above, Altivec load on POWER7 and below
|
|
/// \sa VecLoad_ALTIVEC, VecLoadAligned
|
|
/// \since Crypto++ 8.0
|
|
inline uint32x4_p VecLoad(const word32 src[4])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(src);
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<word32>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
return (uint32x4_p)vec_xl(0, CONST_V8_CAST(src));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
return (uint32x4_p)vec_xl(0, CONST_V32_CAST(addr));
|
|
#else
|
|
return (uint32x4_p)VecLoad_ALTIVEC(CONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Loads a vector from a word array
|
|
/// \param src the word array
|
|
/// \param off offset into the word array
|
|
/// \details VecLoad() loads a vector from a word array.
|
|
/// \details VecLoad() uses POWER7's and VSX's <tt>vec_xl</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecLoad_ALTIVEC() is used if POWER7 is not available.
|
|
/// VecLoad_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \par Wraps
|
|
/// vec_xl on VSX or POWER8 and above, Altivec load on POWER7 and below
|
|
/// \sa VecLoad_ALTIVEC, VecLoadAligned
|
|
/// \since Crypto++ 8.0
|
|
inline uint32x4_p VecLoad(int off, const word32 src[4])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(src)+off;
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<word32>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
return (uint32x4_p)vec_xl(off, CONST_V8_CAST(src));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
return (uint32x4_p)vec_xl(0, CONST_V32_CAST(addr));
|
|
#else
|
|
return (uint32x4_p)VecLoad_ALTIVEC(CONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
#if defined(__VSX__) || defined(_ARCH_PWR8) || defined(CRYPTOPP_DOXYGEN_PROCESSING)
|
|
|
|
/// \brief Loads a vector from a double word array
|
|
/// \param src the double word array
|
|
/// \details VecLoad() loads a vector from a double word array.
|
|
/// \details VecLoad() uses POWER7's and VSX's <tt>vec_xl</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecLoad_ALTIVEC() is used if POWER7 and VSX are not available.
|
|
/// VecLoad_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \details VecLoad() with 64-bit elements is available on POWER7 and above.
|
|
/// \par Wraps
|
|
/// vec_xl on VSX or POWER8 and above, Altivec load on POWER7 and below
|
|
/// \sa VecLoad_ALTIVEC, VecLoadAligned
|
|
/// \since Crypto++ 8.0
|
|
inline uint64x2_p VecLoad(const word64 src[2])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(src);
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<word64>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
return (uint64x2_p)vec_xl(0, CONST_V8_CAST(src));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
// The 32-bit cast is not a typo. Compiler workaround.
|
|
return (uint64x2_p)vec_xl(0, CONST_V32_CAST(addr));
|
|
#else
|
|
return (uint64x2_p)VecLoad_ALTIVEC(CONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Loads a vector from a double word array
|
|
/// \param src the double word array
|
|
/// \param off offset into the double word array
|
|
/// \details VecLoad() loads a vector from a double word array.
|
|
/// \details VecLoad() uses POWER7's and VSX's <tt>vec_xl</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecLoad_ALTIVEC() is used if POWER7 and VSX are not available.
|
|
/// VecLoad_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \details VecLoad() with 64-bit elements is available on POWER8 and above.
|
|
/// \par Wraps
|
|
/// vec_xl on VSX or POWER8 and above, Altivec load on POWER7 and below
|
|
/// \sa VecLoad_ALTIVEC, VecLoadAligned
|
|
/// \since Crypto++ 8.0
|
|
inline uint64x2_p VecLoad(int off, const word64 src[2])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(src)+off;
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<word64>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
return (uint64x2_p)vec_xl(off, CONST_V8_CAST(src));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
// The 32-bit cast is not a typo. Compiler workaround.
|
|
return (uint64x2_p)vec_xl(0, CONST_V32_CAST(addr));
|
|
#else
|
|
return (uint64x2_p)VecLoad_ALTIVEC(CONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
#endif // VSX or ARCH_PWR8
|
|
|
|
/// \brief Loads a vector from an aligned byte array
|
|
/// \param src the byte array
|
|
/// \details VecLoadAligned() loads a vector from an aligned byte array.
|
|
/// \details VecLoadAligned() uses POWER9's <tt>vec_xl</tt> if available.
|
|
/// <tt>vec_ld</tt> is used if POWER9 is not available. The effective
|
|
/// address of <tt>src</tt> must be 16-byte aligned for Altivec.
|
|
/// \par Wraps
|
|
/// vec_xl on POWER9, vec_ld on POWER8 and below
|
|
/// \sa VecLoad_ALTIVEC, VecLoad
|
|
/// \since Crypto++ 8.0
|
|
inline uint32x4_p VecLoadAligned(const byte src[16])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(src);
|
|
CRYPTOPP_ASSERT(addr % 16 == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
return (uint32x4_p)vec_xl(0, CONST_V8_CAST(src));
|
|
#else
|
|
return (uint32x4_p)vec_ld(0, CONST_V8_CAST(src));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Loads a vector from an aligned byte array
|
|
/// \param src the byte array
|
|
/// \param off offset into the src byte array
|
|
/// \details VecLoadAligned() loads a vector from an aligned byte array.
|
|
/// \details VecLoadAligned() uses POWER9's <tt>vec_xl</tt> if available.
|
|
/// <tt>vec_ld</tt> is used if POWER9 is not available. The effective
|
|
/// address of <tt>src</tt> must be 16-byte aligned for Altivec.
|
|
/// \par Wraps
|
|
/// vec_xl on POWER9, vec_ld on POWER8 and below
|
|
/// \sa VecLoad_ALTIVEC, VecLoad
|
|
/// \since Crypto++ 8.0
|
|
inline uint32x4_p VecLoadAligned(int off, const byte src[16])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(src)+off;
|
|
CRYPTOPP_ASSERT(addr % 16 == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
return (uint32x4_p)vec_xl(off, CONST_V8_CAST(src));
|
|
#else
|
|
return (uint32x4_p)vec_ld(off, CONST_V8_CAST(src));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Loads a vector from an aligned word array
|
|
/// \param src the word array
|
|
/// \details VecLoadAligned() loads a vector from an aligned word array.
|
|
/// \details VecLoadAligned() uses POWER7's and VSX's <tt>vec_xl</tt> if
|
|
/// available. <tt>vec_ld</tt> is used if POWER7 or VSX are not available.
|
|
/// The effective address of <tt>src</tt> must be 16-byte aligned for Altivec.
|
|
/// \par Wraps
|
|
/// vec_xl on VSX or POWER8 and above, vec_ld on POWER7 and below
|
|
/// \sa VecLoad_ALTIVEC, VecLoad
|
|
/// \since Crypto++ 8.0
|
|
inline uint32x4_p VecLoadAligned(const word32 src[4])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(src);
|
|
CRYPTOPP_ASSERT(addr % 16 == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
return (uint32x4_p)vec_xl(0, CONST_V8_CAST(src));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
return (uint32x4_p)vec_xl(0, CONST_V32_CAST(src));
|
|
#else
|
|
return (uint32x4_p)vec_ld(0, CONST_V8_CAST(src));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Loads a vector from an aligned word array
|
|
/// \param src the word array
|
|
/// \param off offset into the src word array
|
|
/// \details VecLoadAligned() loads a vector from an aligned word array.
|
|
/// \details VecLoadAligned() uses POWER7's and VSX's <tt>vec_xl</tt> if
|
|
/// available. <tt>vec_ld</tt> is used if POWER7 or VSX are not available.
|
|
/// The effective address of <tt>src</tt> must be 16-byte aligned for Altivec.
|
|
/// \par Wraps
|
|
/// vec_xl on VSX or POWER8 and above, vec_ld on POWER7 and below
|
|
/// \sa VecLoad_ALTIVEC, VecLoad
|
|
/// \since Crypto++ 8.0
|
|
inline uint32x4_p VecLoadAligned(int off, const word32 src[4])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(src)+off;
|
|
CRYPTOPP_ASSERT(addr % 16 == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
return (uint32x4_p)vec_xl(off, CONST_V8_CAST(src));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
return (uint32x4_p)vec_xl(0, CONST_V32_CAST(addr));
|
|
#else
|
|
return (uint32x4_p)vec_ld(off, CONST_V8_CAST(src));
|
|
#endif
|
|
}
|
|
|
|
#if defined(__VSX__) || defined(_ARCH_PWR8) || defined(CRYPTOPP_DOXYGEN_PROCESSING)
|
|
|
|
/// \brief Loads a vector from an aligned double word array
|
|
/// \param src the double word array
|
|
/// \details VecLoadAligned() loads a vector from an aligned double word array.
|
|
/// \details VecLoadAligned() uses POWER7's and VSX's <tt>vec_xl</tt> if
|
|
/// available. <tt>vec_ld</tt> is used if POWER7 or VSX are not available.
|
|
/// The effective address of <tt>src</tt> must be 16-byte aligned for Altivec.
|
|
/// \par Wraps
|
|
/// vec_xl on VSX or POWER8 and above, vec_ld on POWER7 and below
|
|
/// \sa VecLoad_ALTIVEC, VecLoad
|
|
/// \since Crypto++ 8.0
|
|
inline uint64x2_p VecLoadAligned(const word64 src[4])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(src);
|
|
CRYPTOPP_ASSERT(addr % 16 == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
return (uint64x2_p)vec_xl(0, CONST_V8_CAST(src));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
// The 32-bit cast is not a typo. Compiler workaround.
|
|
return (uint64x2_p)vec_xl(0, CONST_V32_CAST(src));
|
|
#else
|
|
return (uint64x2_p)vec_ld(0, CONST_V8_CAST(src));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Loads a vector from an aligned double word array
|
|
/// \param src the double word array
|
|
/// \param off offset into the src double word array
|
|
/// \details VecLoadAligned() loads a vector from an aligned double word array.
|
|
/// \details VecLoadAligned() uses POWER7's and VSX's <tt>vec_xl</tt> if
|
|
/// available. <tt>vec_ld</tt> is used if POWER7 or VSX are not available.
|
|
/// The effective address of <tt>src</tt> must be 16-byte aligned for Altivec.
|
|
/// \par Wraps
|
|
/// vec_xl on VSX or POWER8 and above, vec_ld on POWER7 and below
|
|
/// \sa VecLoad_ALTIVEC, VecLoad
|
|
/// \since Crypto++ 8.0
|
|
inline uint64x2_p VecLoadAligned(int off, const word64 src[4])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(src)+off;
|
|
CRYPTOPP_ASSERT(addr % 16 == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
return (uint64x2_p)vec_xl(off, CONST_V8_CAST(src));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
// The 32-bit cast is not a typo. Compiler workaround.
|
|
return (uint64x2_p)vec_xl(0, CONST_V32_CAST(addr));
|
|
#else
|
|
return (uint64x2_p)vec_ld(off, CONST_V8_CAST(src));
|
|
#endif
|
|
}
|
|
|
|
#endif
|
|
|
|
/// \brief Loads a vector from a byte array
|
|
/// \param src the byte array
|
|
/// \details VecLoadBE() loads a vector from a byte array. VecLoadBE
|
|
/// will reverse all bytes in the array on a little endian system.
|
|
/// \details VecLoadBE() uses POWER7's and VSX's <tt>vec_xl</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecLoad_ALTIVEC() is used if POWER7 or VSX are not available.
|
|
/// VecLoad_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \par Wraps
|
|
/// vec_xl on POWER8, Altivec load on POWER7 and below
|
|
/// \sa VecLoad_ALTIVEC, VecLoad, VecLoadAligned
|
|
/// \since Crypto++ 6.0
|
|
inline uint32x4_p VecLoadBE(const byte src[16])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(src);
|
|
// CRYPTOPP_ASSERT(addr % GetAlignmentOf<byte>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<byte>() == 0);
|
|
return (uint32x4_p)vec_xl_be(0, CONST_V8_CAST(src));
|
|
#elif defined(CRYPTOPP_BIG_ENDIAN)
|
|
return (uint32x4_p)VecLoad_ALTIVEC(0, CONST_V8_CAST(src));
|
|
#else
|
|
return (uint32x4_p)VecReverseLE(VecLoad_ALTIVEC(CONST_V8_CAST(src)));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Loads a vector from a byte array
|
|
/// \param src the byte array
|
|
/// \param off offset into the src byte array
|
|
/// \details VecLoadBE() loads a vector from a byte array. VecLoadBE
|
|
/// will reverse all bytes in the array on a little endian system.
|
|
/// \details VecLoadBE() uses POWER7's and VSX's <tt>vec_xl</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecLoad_ALTIVEC() is used if POWER7 is not available.
|
|
/// VecLoad_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \par Wraps
|
|
/// vec_xl on POWER8, Altivec load on POWER7 and below
|
|
/// \sa VecLoad_ALTIVEC, VecLoad, VecLoadAligned
|
|
/// \since Crypto++ 6.0
|
|
inline uint32x4_p VecLoadBE(int off, const byte src[16])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(src)+off;
|
|
// CRYPTOPP_ASSERT(addr % GetAlignmentOf<byte>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<byte>() == 0);
|
|
return (uint32x4_p)vec_xl_be(off, CONST_V8_CAST(src));
|
|
#elif defined(CRYPTOPP_BIG_ENDIAN)
|
|
return (uint32x4_p)VecLoad_ALTIVEC(CONST_V8_CAST(addr));
|
|
#else
|
|
return (uint32x4_p)VecReverseLE(VecLoad_ALTIVEC(CONST_V8_CAST(addr)));
|
|
#endif
|
|
}
|
|
|
|
//@}
|
|
|
|
/// \name STORE OPERATIONS
|
|
//@{
|
|
|
|
/// \brief Stores a vector to a byte array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param dest the byte array
|
|
/// \details VecStore_ALTIVEC() stores a vector to a byte array.
|
|
/// \details VecStore_ALTIVEC() uses <tt>vec_st</tt> if the effective address
|
|
/// of <tt>dest</tt> is aligned, and uses <tt>vec_ste</tt> otherwise.
|
|
/// <tt>vec_ste</tt> is relatively expensive so you should provide aligned
|
|
/// memory addresses.
|
|
/// \details VecStore_ALTIVEC() is used when POWER7 or above
|
|
/// and unaligned loads is not available.
|
|
/// \par Wraps
|
|
/// vec_st, vec_ste, vec_lvsr, vec_perm
|
|
/// \sa VecStore, VecStoreAligned
|
|
/// \since Crypto++ 8.0
|
|
template<class T>
|
|
inline void VecStore_ALTIVEC(const T data, byte dest[16])
|
|
{
|
|
// Avoid IsAlignedOn for convenience.
|
|
uintptr_t addr = reinterpret_cast<uintptr_t>(dest);
|
|
if (addr % 16 == 0)
|
|
{
|
|
vec_st((uint8x16_p)data, 0, NCONST_V8_CAST(addr));
|
|
}
|
|
else
|
|
{
|
|
// http://www.nxp.com/docs/en/reference-manual/ALTIVECPEM.pdf
|
|
uint8x16_p perm = (uint8x16_p)vec_perm(data, data, vec_lvsr(0, NCONST_V8_CAST(addr)));
|
|
vec_ste((uint8x16_p) perm, 0, (unsigned char*) NCONST_V8_CAST(addr));
|
|
vec_ste((uint16x8_p) perm, 1, (unsigned short*)NCONST_V8_CAST(addr));
|
|
vec_ste((uint32x4_p) perm, 3, (unsigned int*) NCONST_V8_CAST(addr));
|
|
vec_ste((uint32x4_p) perm, 4, (unsigned int*) NCONST_V8_CAST(addr));
|
|
vec_ste((uint32x4_p) perm, 8, (unsigned int*) NCONST_V8_CAST(addr));
|
|
vec_ste((uint32x4_p) perm, 12, (unsigned int*) NCONST_V8_CAST(addr));
|
|
vec_ste((uint16x8_p) perm, 14, (unsigned short*)NCONST_V8_CAST(addr));
|
|
vec_ste((uint8x16_p) perm, 15, (unsigned char*) NCONST_V8_CAST(addr));
|
|
}
|
|
}
|
|
|
|
/// \brief Stores a vector to a byte array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param off offset into the dest byte array
|
|
/// \param dest the byte array
|
|
/// \details VecStore_ALTIVEC() stores a vector to a byte array.
|
|
/// \details VecStore_ALTIVEC() uses <tt>vec_st</tt> if the effective address
|
|
/// of <tt>dest</tt> is aligned, and uses <tt>vec_ste</tt> otherwise.
|
|
/// <tt>vec_ste</tt> is relatively expensive so you should provide aligned
|
|
/// memory addresses.
|
|
/// \details VecStore_ALTIVEC() is used when POWER7 or above
|
|
/// and unaligned loads is not available.
|
|
/// \par Wraps
|
|
/// vec_st, vec_ste, vec_lvsr, vec_perm
|
|
/// \sa VecStore, VecStoreAligned
|
|
/// \since Crypto++ 8.0
|
|
template<class T>
|
|
inline void VecStore_ALTIVEC(const T data, int off, byte dest[16])
|
|
{
|
|
// Avoid IsAlignedOn for convenience.
|
|
uintptr_t addr = reinterpret_cast<uintptr_t>(dest)+off;
|
|
if (addr % 16 == 0)
|
|
{
|
|
vec_st((uint8x16_p)data, 0, NCONST_V8_CAST(addr));
|
|
}
|
|
else
|
|
{
|
|
// http://www.nxp.com/docs/en/reference-manual/ALTIVECPEM.pdf
|
|
uint8x16_p perm = (uint8x16_p)vec_perm(data, data, vec_lvsr(0, NCONST_V8_CAST(addr)));
|
|
vec_ste((uint8x16_p) perm, 0, (unsigned char*) NCONST_V8_CAST(addr));
|
|
vec_ste((uint16x8_p) perm, 1, (unsigned short*)NCONST_V8_CAST(addr));
|
|
vec_ste((uint32x4_p) perm, 3, (unsigned int*) NCONST_V8_CAST(addr));
|
|
vec_ste((uint32x4_p) perm, 4, (unsigned int*) NCONST_V8_CAST(addr));
|
|
vec_ste((uint32x4_p) perm, 8, (unsigned int*) NCONST_V8_CAST(addr));
|
|
vec_ste((uint32x4_p) perm, 12, (unsigned int*) NCONST_V8_CAST(addr));
|
|
vec_ste((uint16x8_p) perm, 14, (unsigned short*)NCONST_V8_CAST(addr));
|
|
vec_ste((uint8x16_p) perm, 15, (unsigned char*) NCONST_V8_CAST(addr));
|
|
}
|
|
}
|
|
|
|
/// \brief Stores a vector to a byte array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param dest the byte array
|
|
/// \details VecStore() stores a vector to a byte array.
|
|
/// \details VecStore() uses POWER9's <tt>vec_xst</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecStore_ALTIVEC() is used if POWER9 is not available.
|
|
/// VecStore_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \par Wraps
|
|
/// vec_xst on POWER9 and above, Altivec store on POWER8 and below
|
|
/// \sa VecStore_ALTIVEC, VecStoreAligned
|
|
/// \since Crypto++ 6.0
|
|
template<class T>
|
|
inline void VecStore(const T data, byte dest[16])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest);
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<byte>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst((uint8x16_p)data, 0, NCONST_V8_CAST(dest));
|
|
#else
|
|
VecStore_ALTIVEC((uint8x16_p)data, NCONST_V8_CAST(dest));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Stores a vector to a byte array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param off offset into the dest byte array
|
|
/// \param dest the byte array
|
|
/// \details VecStore() stores a vector to a byte array.
|
|
/// \details VecStore() uses POWER9's <tt>vec_xst</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecStore_ALTIVEC() is used if POWER9 is not available.
|
|
/// VecStore_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \par Wraps
|
|
/// vec_xst on POWER9 and above, Altivec store on POWER8 and below
|
|
/// \sa VecStore_ALTIVEC, VecStoreAligned
|
|
/// \since Crypto++ 6.0
|
|
template<class T>
|
|
inline void VecStore(const T data, int off, byte dest[16])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest)+off;
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<byte>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst((uint8x16_p)data, off, NCONST_V8_CAST(dest));
|
|
#else
|
|
VecStore_ALTIVEC((uint8x16_p)data, NCONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Stores a vector to a word array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param dest the word array
|
|
/// \details VecStore() stores a vector to a word array.
|
|
/// \details VecStore() uses POWER7's and VSX's <tt>vec_xst</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecStore_ALTIVEC() is used if POWER7 or VSX are not available.
|
|
/// VecStore_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \par Wraps
|
|
/// vec_xst on VSX or POWER8 and above, Altivec store on POWER7 and below
|
|
/// \sa VecStore_ALTIVEC, VecStoreAligned
|
|
/// \since Crypto++ 8.0
|
|
template<class T>
|
|
inline void VecStore(const T data, word32 dest[4])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xst, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks stores for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xst for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest);
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<word32>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst((uint8x16_p)data, 0, NCONST_V8_CAST(dest));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
vec_xst((uint32x4_p)data, 0, NCONST_V32_CAST(addr));
|
|
#else
|
|
VecStore_ALTIVEC((uint8x16_p)data, NCONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Stores a vector to a word array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param off offset into the dest word array
|
|
/// \param dest the word array
|
|
/// \details VecStore() stores a vector to a word array.
|
|
/// \details VecStore() uses POWER7's and VSX's <tt>vec_xst</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecStore_ALTIVEC() is used if POWER7 or VSX are not available.
|
|
/// VecStore_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \par Wraps
|
|
/// vec_xst on VSX or POWER8 and above, Altivec store on POWER7 and below
|
|
/// \sa VecStore_ALTIVEC, VecStoreAligned
|
|
/// \since Crypto++ 8.0
|
|
template<class T>
|
|
inline void VecStore(const T data, int off, word32 dest[4])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xst, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks stores for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xst for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest)+off;
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<word32>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst((uint8x16_p)data, off, NCONST_V8_CAST(dest));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
vec_xst((uint32x4_p)data, 0, NCONST_V32_CAST(addr));
|
|
#else
|
|
VecStore_ALTIVEC((uint8x16_p)data, NCONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Stores a vector to a word array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param dest the word array
|
|
/// \details VecStore() stores a vector to a word array.
|
|
/// \details VecStore() uses POWER7's and VSX's <tt>vec_xst</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecStore_ALTIVEC() is used if POWER7 or VSX are not available.
|
|
/// VecStore_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \details VecStore() with 64-bit elements is available on POWER8 and above.
|
|
/// \par Wraps
|
|
/// vec_xst on VSX or POWER8 and above, Altivec store on POWER7 and below
|
|
/// \sa VecStore_ALTIVEC, VecStoreAligned
|
|
/// \since Crypto++ 8.0
|
|
template<class T>
|
|
inline void VecStore(const T data, word64 dest[2])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xst, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks stores for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xst for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest);
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<word64>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst((uint8x16_p)data, 0, NCONST_V8_CAST(dest));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
// 32-bit cast is not a typo. Compiler workaround.
|
|
vec_xst((uint32x4_p)data, 0, NCONST_V32_CAST(addr));
|
|
#else
|
|
VecStore_ALTIVEC((uint8x16_p)data, NCONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Stores a vector to a word array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param off offset into the dest word array
|
|
/// \param dest the word array
|
|
/// \details VecStore() stores a vector to a word array.
|
|
/// \details VecStore() uses POWER7's and VSX's <tt>vec_xst</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecStore_ALTIVEC() is used if POWER7 or VSX are not available.
|
|
/// VecStore_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \details VecStore() with 64-bit elements is available on POWER8 and above.
|
|
/// \par Wraps
|
|
/// vec_xst on VSX or POWER8 and above, Altivec store on POWER7 and below
|
|
/// \sa VecStore_ALTIVEC, VecStoreAligned
|
|
/// \since Crypto++ 8.0
|
|
template<class T>
|
|
inline void VecStore(const T data, int off, word64 dest[2])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xst, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks stores for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xst for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest)+off;
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<word64>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst((uint8x16_p)data, off, NCONST_V8_CAST(dest));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
// 32-bit cast is not a typo. Compiler workaround.
|
|
vec_xst((uint32x4_p)data, 0, NCONST_V32_CAST(addr));
|
|
#else
|
|
VecStore_ALTIVEC((uint8x16_p)data, NCONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Stores a vector to a byte array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param dest the byte array
|
|
/// \details VecStoreAligned() stores a vector from an aligned byte array.
|
|
/// \details VecStoreAligned() uses POWER9's <tt>vec_xl</tt> if available.
|
|
/// <tt>vec_st</tt> is used if POWER9 is not available. The effective
|
|
/// address of <tt>dest</tt> must be 16-byte aligned for Altivec.
|
|
/// \par Wraps
|
|
/// vec_xst on POWER9 or above, vec_st on POWER8 and below
|
|
/// \sa VecStore_ALTIVEC, VecStore
|
|
/// \since Crypto++ 8.0
|
|
template<class T>
|
|
inline void VecStoreAligned(const T data, byte dest[16])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest);
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<byte>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst((uint8x16_p)data, 0, NCONST_V8_CAST(dest));
|
|
#else
|
|
vec_st((uint8x16_p)data, 0, NCONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Stores a vector to a byte array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param off offset into the dest byte array
|
|
/// \param dest the byte array
|
|
/// \details VecStoreAligned() stores a vector from an aligned byte array.
|
|
/// \details VecStoreAligned() uses POWER9's <tt>vec_xl</tt> if available.
|
|
/// <tt>vec_st</tt> is used if POWER9 is not available. The effective
|
|
/// address of <tt>dest</tt> must be 16-byte aligned for Altivec.
|
|
/// \par Wraps
|
|
/// vec_xst on POWER9 or above, vec_st on POWER8 and below
|
|
/// \sa VecStore_ALTIVEC, VecStore
|
|
/// \since Crypto++ 8.0
|
|
template<class T>
|
|
inline void VecStoreAligned(const T data, int off, byte dest[16])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xl, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks loads for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xl for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest)+off;
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<byte>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst((uint8x16_p)data, off, NCONST_V8_CAST(dest));
|
|
#else
|
|
vec_st((uint8x16_p)data, 0, NCONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Stores a vector to a word array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param dest the word array
|
|
/// \details VecStoreAligned() stores a vector from an aligned word array.
|
|
/// \details VecStoreAligned() uses POWER9's <tt>vec_xl</tt> if available.
|
|
/// POWER7 <tt>vec_xst</tt> is used if POWER9 is not available. <tt>vec_st</tt>
|
|
/// is used if POWER7 is not available. The effective address of <tt>dest</tt>
|
|
/// must be 16-byte aligned for Altivec.
|
|
/// \par Wraps
|
|
/// vec_xst on VSX or POWER8 and above, vec_st on POWER7 and below
|
|
/// \sa VecStore_ALTIVEC, VecStore
|
|
/// \since Crypto++ 8.0
|
|
template<class T>
|
|
inline void VecStoreAligned(const T data, word32 dest[4])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xst, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks stores for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xst for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest);
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<word32>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst((uint8x16_p)data, 0, NCONST_V8_CAST(dest));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
vec_xst((uint32x4_p)data, 0, NCONST_V32_CAST(addr));
|
|
#else
|
|
vec_st((uint8x16_p)data, 0, NCONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Stores a vector to a word array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param off offset into the dest word array
|
|
/// \param dest the word array
|
|
/// \details VecStoreAligned() stores a vector from an aligned word array.
|
|
/// \details VecStoreAligned() uses POWER9's <tt>vec_xl</tt> if available.
|
|
/// POWER7 <tt>vec_xst</tt> is used if POWER9 is not available. <tt>vec_st</tt>
|
|
/// is used if POWER7 is not available. The effective address of <tt>dest</tt>
|
|
/// must be 16-byte aligned for Altivec.
|
|
/// \par Wraps
|
|
/// vec_xst on VSX or POWER8 and above, vec_st on POWER7 and below
|
|
/// \sa VecStore_ALTIVEC, VecStore
|
|
/// \since Crypto++ 8.0
|
|
template<class T>
|
|
inline void VecStoreAligned(const T data, int off, word32 dest[4])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xst, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks stores for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xst for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest)+off;
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<word32>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst((uint8x16_p)data, off, NCONST_V8_CAST(dest));
|
|
#elif defined(__VSX__) || defined(_ARCH_PWR8)
|
|
vec_xst((uint32x4_p)data, 0, NCONST_V32_CAST(addr));
|
|
#else
|
|
vec_st((uint8x16_p)data, 0, NCONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Stores a vector to a byte array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param dest the byte array
|
|
/// \details VecStoreBE() stores a vector to a byte array. VecStoreBE
|
|
/// will reverse all bytes in the array on a little endian system.
|
|
/// \details VecStoreBE() uses POWER7's and VSX's <tt>vec_xst</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecStore_ALTIVEC() is used if POWER7 is not available.
|
|
/// VecStore_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \par Wraps
|
|
/// vec_xst on VSX or POWER8 and above, vec_st on POWER7 and below
|
|
/// \sa VecStore_ALTIVEC, VecStoreAligned
|
|
/// \since Crypto++ 6.0
|
|
template <class T>
|
|
inline void VecStoreBE(const T data, byte dest[16])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xst, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks stores for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xst for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest);
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<byte>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst_be((uint8x16_p)data, 0, NCONST_V8_CAST(dest));
|
|
#elif defined(CRYPTOPP_BIG_ENDIAN)
|
|
VecStore((uint8x16_p)data, NCONST_V8_CAST(addr));
|
|
#else
|
|
VecStore((uint8x16_p)VecReverseLE(data), NCONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Stores a vector to a byte array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param off offset into the dest byte array
|
|
/// \param dest the byte array
|
|
/// \details VecStoreBE() stores a vector to a byte array. VecStoreBE
|
|
/// will reverse all bytes in the array on a little endian system.
|
|
/// \details VecStoreBE() uses POWER7's and VSX's <tt>vec_xst</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecStore_ALTIVEC() is used if POWER7 is not available.
|
|
/// VecStore_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \par Wraps
|
|
/// vec_xst on VSX or POWER8 and above, vec_st on POWER7 and below
|
|
/// \sa VecStore_ALTIVEC, VecStoreAligned
|
|
/// \since Crypto++ 6.0
|
|
template <class T>
|
|
inline void VecStoreBE(const T data, int off, byte dest[16])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xst, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks stores for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xst for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest)+off;
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<byte>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst_be((uint8x16_p)data, off, NCONST_V8_CAST(dest));
|
|
#elif defined(CRYPTOPP_BIG_ENDIAN)
|
|
VecStore((uint8x16_p)data, NCONST_V8_CAST(addr));
|
|
#else
|
|
VecStore((uint8x16_p)VecReverseLE(data), NCONST_V8_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Stores a vector to a word array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param dest the word array
|
|
/// \details VecStoreBE() stores a vector to a word array. VecStoreBE
|
|
/// will reverse all bytes in the array on a little endian system.
|
|
/// \details VecStoreBE() uses POWER7's and VSX's <tt>vec_xst</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecStore_ALTIVEC() is used if POWER7 is not available.
|
|
/// VecStore_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \par Wraps
|
|
/// vec_xst on VSX or POWER8 and above, vec_st on POWER7 and below
|
|
/// \sa VecStore_ALTIVEC, VecStoreAligned
|
|
/// \since Crypto++ 8.0
|
|
template <class T>
|
|
inline void VecStoreBE(const T data, word32 dest[4])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xst, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks stores for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xst for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest);
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<word32>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst_be((uint8x16_p)data, 0, NCONST_V8_CAST(dest));
|
|
#elif defined(CRYPTOPP_BIG_ENDIAN)
|
|
VecStore((uint32x4_p)data, NCONST_V32_CAST(addr));
|
|
#else
|
|
VecStore((uint32x4_p)VecReverseLE(data), NCONST_V32_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Stores a vector to a word array
|
|
/// \tparam T vector type
|
|
/// \param data the vector
|
|
/// \param off offset into the dest word array
|
|
/// \param dest the word array
|
|
/// \details VecStoreBE() stores a vector to a word array. VecStoreBE
|
|
/// will reverse all words in the array on a little endian system.
|
|
/// \details VecStoreBE() uses POWER7's and VSX's <tt>vec_xst</tt> if available.
|
|
/// The instruction does not require aligned effective memory addresses.
|
|
/// VecStore_ALTIVEC() is used if POWER7 is not available.
|
|
/// VecStore_ALTIVEC() can be relatively expensive if extra instructions
|
|
/// are required to fix up unaligned memory addresses.
|
|
/// \par Wraps
|
|
/// vec_xst on VSX or POWER8 and above, vec_st on POWER7 and below
|
|
/// \sa VecStore_ALTIVEC, VecStoreAligned
|
|
/// \since Crypto++ 8.0
|
|
template <class T>
|
|
inline void VecStoreBE(const T data, int off, word32 dest[4])
|
|
{
|
|
// Power7/ISA 2.06 provides vec_xst, but only for 32-bit and 64-bit
|
|
// word pointers. The ISA lacks stores for short* and char*.
|
|
// Power9/ISA 3.0 provides vec_xst for all datatypes.
|
|
|
|
const uintptr_t addr = reinterpret_cast<uintptr_t>(dest)+off;
|
|
CRYPTOPP_ASSERT(addr % GetAlignmentOf<word32>() == 0);
|
|
CRYPTOPP_UNUSED(addr);
|
|
|
|
#if defined(_ARCH_PWR9)
|
|
vec_xst_be((uint8x16_p)data, off, NCONST_V8_CAST(dest));
|
|
#elif defined(CRYPTOPP_BIG_ENDIAN)
|
|
VecStore((uint32x4_p)data, NCONST_V32_CAST(addr));
|
|
#else
|
|
VecStore((uint32x4_p)VecReverseLE(data), NCONST_V32_CAST(addr));
|
|
#endif
|
|
}
|
|
|
|
//@}
|
|
|
|
/// \name LOGICAL OPERATIONS
|
|
//@{
|
|
|
|
/// \brief AND two vectors
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \return vector
|
|
/// \details VecAnd() performs <tt>vec1 & vec2</tt>.
|
|
/// vec2 is cast to the same type as vec1. The return vector
|
|
/// is the same type as vec1.
|
|
/// \par Wraps
|
|
/// vec_and
|
|
/// \sa VecAnd64
|
|
/// \since Crypto++ 6.0
|
|
template <class T1, class T2>
|
|
inline T1 VecAnd(const T1 vec1, const T2 vec2)
|
|
{
|
|
return (T1)vec_and(vec1, (T1)vec2);
|
|
}
|
|
|
|
/// \brief OR two vectors
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \return vector
|
|
/// \details VecOr() performs <tt>vec1 | vec2</tt>.
|
|
/// vec2 is cast to the same type as vec1. The return vector
|
|
/// is the same type as vec1.
|
|
/// \par Wraps
|
|
/// vec_or
|
|
/// \sa VecOr64
|
|
/// \since Crypto++ 6.0
|
|
template <class T1, class T2>
|
|
inline T1 VecOr(const T1 vec1, const T2 vec2)
|
|
{
|
|
return (T1)vec_or(vec1, (T1)vec2);
|
|
}
|
|
|
|
/// \brief XOR two vectors
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \return vector
|
|
/// \details VecXor() performs <tt>vec1 ^ vec2</tt>.
|
|
/// vec2 is cast to the same type as vec1. The return vector
|
|
/// is the same type as vec1.
|
|
/// \par Wraps
|
|
/// vec_xor
|
|
/// \sa VecXor64
|
|
/// \since Crypto++ 6.0
|
|
template <class T1, class T2>
|
|
inline T1 VecXor(const T1 vec1, const T2 vec2)
|
|
{
|
|
return (T1)vec_xor(vec1, (T1)vec2);
|
|
}
|
|
|
|
//@}
|
|
|
|
/// \name ARITHMETIC OPERATIONS
|
|
//@{
|
|
|
|
/// \brief Add two vectors
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \return vector
|
|
/// \details VecAdd() performs <tt>vec1 + vec2</tt>.
|
|
/// vec2 is cast to the same type as vec1. The return vector
|
|
/// is the same type as vec1.
|
|
/// \par Wraps
|
|
/// vec_add
|
|
/// \sa VecAdd64
|
|
/// \since Crypto++ 6.0
|
|
template <class T1, class T2>
|
|
inline T1 VecAdd(const T1 vec1, const T2 vec2)
|
|
{
|
|
return (T1)vec_add(vec1, (T1)vec2);
|
|
}
|
|
|
|
/// \brief Subtract two vectors
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \details VecSub() performs <tt>vec1 - vec2</tt>.
|
|
/// vec2 is cast to the same type as vec1. The return vector
|
|
/// is the same type as vec1.
|
|
/// \par Wraps
|
|
/// vec_sub
|
|
/// \sa VecSub64
|
|
/// \since Crypto++ 6.0
|
|
template <class T1, class T2>
|
|
inline T1 VecSub(const T1 vec1, const T2 vec2)
|
|
{
|
|
return (T1)vec_sub(vec1, (T1)vec2);
|
|
}
|
|
|
|
//@}
|
|
|
|
/// \name PERMUTE OPERATIONS
|
|
//@{
|
|
|
|
/// \brief Permutes a vector
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param vec the vector
|
|
/// \param mask vector mask
|
|
/// \return vector
|
|
/// \details VecPermute() creates a new vector from vec according to mask.
|
|
/// mask is an uint8x16_p vector. The return vector is the same type as vec.
|
|
/// \par Wraps
|
|
/// vec_perm
|
|
/// \since Crypto++ 6.0
|
|
template <class T1, class T2>
|
|
inline T1 VecPermute(const T1 vec, const T2 mask)
|
|
{
|
|
return (T1)vec_perm(vec, vec, (uint8x16_p)mask);
|
|
}
|
|
|
|
/// \brief Permutes two vectors
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \param mask vector mask
|
|
/// \return vector
|
|
/// \details VecPermute() creates a new vector from vec1 and vec2 according to mask.
|
|
/// mask is an uint8x16_p vector. The return vector is the same type as vec.
|
|
/// \par Wraps
|
|
/// vec_perm
|
|
/// \since Crypto++ 6.0
|
|
template <class T1, class T2>
|
|
inline T1 VecPermute(const T1 vec1, const T1 vec2, const T2 mask)
|
|
{
|
|
return (T1)vec_perm(vec1, (T1)vec2, (uint8x16_p)mask);
|
|
}
|
|
|
|
//@}
|
|
|
|
/// \name SHIFT AND ROTATE OPERATIONS
|
|
//@{
|
|
|
|
/// \brief Shift a vector left
|
|
/// \tparam C shift byte count
|
|
/// \tparam T vector type
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecShiftLeftOctet() returns a new vector after shifting the
|
|
/// concatenation of the zero vector and the source vector by the specified
|
|
/// number of bytes. The return vector is the same type as vec.
|
|
/// \details On big endian machines VecShiftLeftOctet() is <tt>vec_sld(a, z,
|
|
/// c)</tt>. On little endian machines VecShiftLeftOctet() is translated to
|
|
/// <tt>vec_sld(z, a, 16-c)</tt>. You should always call the function as
|
|
/// if on a big endian machine as shown below.
|
|
/// <pre>
|
|
/// uint8x16_p x = VecLoad(ptr);
|
|
/// uint8x16_p y = VecShiftLeftOctet<12>(x);
|
|
/// </pre>
|
|
/// \par Wraps
|
|
/// vec_sld
|
|
/// \sa <A HREF="https://stackoverflow.com/q/46341923/608639">Is vec_sld
|
|
/// endian sensitive?</A> on Stack Overflow
|
|
/// \since Crypto++ 6.0
|
|
template <unsigned int C, class T>
|
|
inline T VecShiftLeftOctet(const T vec)
|
|
{
|
|
const T zero = {0};
|
|
if (C >= 16)
|
|
{
|
|
// Out of range
|
|
return zero;
|
|
}
|
|
else if (C == 0)
|
|
{
|
|
// Noop
|
|
return vec;
|
|
}
|
|
else
|
|
{
|
|
#if defined(CRYPTOPP_BIG_ENDIAN)
|
|
enum { R=C&0xf };
|
|
return (T)vec_sld((uint8x16_p)vec, (uint8x16_p)zero, R);
|
|
#else
|
|
enum { R=(16-C)&0xf }; // Linux xlC 13.1 workaround in Debug builds
|
|
return (T)vec_sld((uint8x16_p)zero, (uint8x16_p)vec, R);
|
|
#endif
|
|
}
|
|
}
|
|
|
|
/// \brief Shift a vector right
|
|
/// \tparam C shift byte count
|
|
/// \tparam T vector type
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecShiftRightOctet() returns a new vector after shifting the
|
|
/// concatenation of the zero vector and the source vector by the specified
|
|
/// number of bytes. The return vector is the same type as vec.
|
|
/// \details On big endian machines VecShiftRightOctet() is <tt>vec_sld(a, z,
|
|
/// c)</tt>. On little endian machines VecShiftRightOctet() is translated to
|
|
/// <tt>vec_sld(z, a, 16-c)</tt>. You should always call the function as
|
|
/// if on a big endian machine as shown below.
|
|
/// <pre>
|
|
/// uint8x16_p x = VecLoad(ptr);
|
|
/// uint8x16_p y = VecShiftRightOctet<12>(y);
|
|
/// </pre>
|
|
/// \par Wraps
|
|
/// vec_sld
|
|
/// \sa <A HREF="https://stackoverflow.com/q/46341923/608639">Is vec_sld
|
|
/// endian sensitive?</A> on Stack Overflow
|
|
/// \since Crypto++ 6.0
|
|
template <unsigned int C, class T>
|
|
inline T VecShiftRightOctet(const T vec)
|
|
{
|
|
const T zero = {0};
|
|
if (C >= 16)
|
|
{
|
|
// Out of range
|
|
return zero;
|
|
}
|
|
else if (C == 0)
|
|
{
|
|
// Noop
|
|
return vec;
|
|
}
|
|
else
|
|
{
|
|
#if defined(CRYPTOPP_BIG_ENDIAN)
|
|
enum { R=(16-C)&0xf }; // Linux xlC 13.1 workaround in Debug builds
|
|
return (T)vec_sld((uint8x16_p)zero, (uint8x16_p)vec, R);
|
|
#else
|
|
enum { R=C&0xf };
|
|
return (T)vec_sld((uint8x16_p)vec, (uint8x16_p)zero, R);
|
|
#endif
|
|
}
|
|
}
|
|
|
|
/// \brief Rotate a vector left
|
|
/// \tparam C shift byte count
|
|
/// \tparam T vector type
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecRotateLeftOctet() returns a new vector after rotating the
|
|
/// concatenation of the source vector with itself by the specified
|
|
/// number of bytes. The return vector is the same type as vec.
|
|
/// \par Wraps
|
|
/// vec_sld
|
|
/// \sa <A HREF="https://stackoverflow.com/q/46341923/608639">Is vec_sld
|
|
/// endian sensitive?</A> on Stack Overflow
|
|
/// \since Crypto++ 6.0
|
|
template <unsigned int C, class T>
|
|
inline T VecRotateLeftOctet(const T vec)
|
|
{
|
|
#if defined(CRYPTOPP_BIG_ENDIAN)
|
|
enum { R = C&0xf };
|
|
return (T)vec_sld((uint8x16_p)vec, (uint8x16_p)vec, R);
|
|
#else
|
|
enum { R=(16-C)&0xf }; // Linux xlC 13.1 workaround in Debug builds
|
|
return (T)vec_sld((uint8x16_p)vec, (uint8x16_p)vec, R);
|
|
#endif
|
|
}
|
|
|
|
/// \brief Rotate a vector right
|
|
/// \tparam C shift byte count
|
|
/// \tparam T vector type
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecRotateRightOctet() returns a new vector after rotating the
|
|
/// concatenation of the source vector with itself by the specified
|
|
/// number of bytes. The return vector is the same type as vec.
|
|
/// \par Wraps
|
|
/// vec_sld
|
|
/// \sa <A HREF="https://stackoverflow.com/q/46341923/608639">Is vec_sld
|
|
/// endian sensitive?</A> on Stack Overflow
|
|
/// \since Crypto++ 6.0
|
|
template <unsigned int C, class T>
|
|
inline T VecRotateRightOctet(const T vec)
|
|
{
|
|
#if defined(CRYPTOPP_BIG_ENDIAN)
|
|
enum { R=(16-C)&0xf }; // Linux xlC 13.1 workaround in Debug builds
|
|
return (T)vec_sld((uint8x16_p)vec, (uint8x16_p)vec, R);
|
|
#else
|
|
enum { R = C&0xf };
|
|
return (T)vec_sld((uint8x16_p)vec, (uint8x16_p)vec, R);
|
|
#endif
|
|
}
|
|
|
|
/// \brief Rotate a vector left
|
|
/// \tparam C rotate bit count
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecRotateLeft() rotates each element in a vector by
|
|
/// bit count. The return vector is the same type as vec.
|
|
/// \par Wraps
|
|
/// vec_rl
|
|
/// \since Crypto++ 7.0
|
|
template<unsigned int C>
|
|
inline uint32x4_p VecRotateLeft(const uint32x4_p vec)
|
|
{
|
|
const uint32x4_p m = {C, C, C, C};
|
|
return vec_rl(vec, m);
|
|
}
|
|
|
|
/// \brief Rotate a vector right
|
|
/// \tparam C rotate bit count
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecRotateRight() rotates each element in a vector
|
|
/// by bit count. The return vector is the same type as vec.
|
|
/// \par Wraps
|
|
/// vec_rl
|
|
/// \since Crypto++ 7.0
|
|
template<unsigned int C>
|
|
inline uint32x4_p VecRotateRight(const uint32x4_p vec)
|
|
{
|
|
const uint32x4_p m = {32-C, 32-C, 32-C, 32-C};
|
|
return vec_rl(vec, m);
|
|
}
|
|
|
|
/// \brief Shift a vector left
|
|
/// \tparam C shift bit count
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecShiftLeft() rotates each element in a vector
|
|
/// by bit count. The return vector is the same type as vec.
|
|
/// \par Wraps
|
|
/// vec_sl
|
|
/// \since Crypto++ 8.1
|
|
template<unsigned int C>
|
|
inline uint32x4_p VecShiftLeft(const uint32x4_p vec)
|
|
{
|
|
const uint32x4_p m = {C, C, C, C};
|
|
return vec_sl(vec, m);
|
|
}
|
|
|
|
/// \brief Shift a vector right
|
|
/// \tparam C shift bit count
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecShiftRight() rotates each element in a vector
|
|
/// by bit count. The return vector is the same type as vec.
|
|
/// \par Wraps
|
|
/// vec_rl
|
|
/// \since Crypto++ 8.1
|
|
template<unsigned int C>
|
|
inline uint32x4_p VecShiftRight(const uint32x4_p vec)
|
|
{
|
|
const uint32x4_p m = {C, C, C, C};
|
|
return vec_sr(vec, m);
|
|
}
|
|
|
|
// 64-bit elements available at POWER7 with VSX, but vec_rl and vec_sl require POWER8
|
|
#if defined(_ARCH_PWR8) || defined(CRYPTOPP_DOXYGEN_PROCESSING)
|
|
|
|
/// \brief Rotate a vector left
|
|
/// \tparam C rotate bit count
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecRotateLeft() rotates each element in a vector
|
|
/// by bit count. The return vector is the same type as vec.
|
|
/// \details VecRotateLeft() with 64-bit elements is available on
|
|
/// POWER8 and above.
|
|
/// \par Wraps
|
|
/// vec_rl
|
|
/// \since Crypto++ 8.0
|
|
template<unsigned int C>
|
|
inline uint64x2_p VecRotateLeft(const uint64x2_p vec)
|
|
{
|
|
const uint64x2_p m = {C, C};
|
|
return vec_rl(vec, m);
|
|
}
|
|
|
|
/// \brief Shift a vector left
|
|
/// \tparam C shift bit count
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecShiftLeft() rotates each element in a vector
|
|
/// by bit count. The return vector is the same type as vec.
|
|
/// \details VecShiftLeft() with 64-bit elements is available on
|
|
/// POWER8 and above.
|
|
/// \par Wraps
|
|
/// vec_sl
|
|
/// \since Crypto++ 8.1
|
|
template<unsigned int C>
|
|
inline uint64x2_p VecShiftLeft(const uint64x2_p vec)
|
|
{
|
|
const uint64x2_p m = {C, C};
|
|
return vec_sl(vec, m);
|
|
}
|
|
|
|
/// \brief Rotate a vector right
|
|
/// \tparam C rotate bit count
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecRotateRight() rotates each element in a vector
|
|
/// by bit count. The return vector is the same type as vec.
|
|
/// \details VecRotateRight() with 64-bit elements is available on
|
|
/// POWER8 and above.
|
|
/// \par Wraps
|
|
/// vec_rl
|
|
/// \since Crypto++ 8.0
|
|
template<unsigned int C>
|
|
inline uint64x2_p VecRotateRight(const uint64x2_p vec)
|
|
{
|
|
const uint64x2_p m = {64-C, 64-C};
|
|
return vec_rl(vec, m);
|
|
}
|
|
|
|
/// \brief Shift a vector right
|
|
/// \tparam C shift bit count
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecShiftRight() rotates each element in a vector
|
|
/// by bit count. The return vector is the same type as vec.
|
|
/// \details VecShiftRight() with 64-bit elements is available on
|
|
/// POWER8 and above.
|
|
/// \par Wraps
|
|
/// vec_sr
|
|
/// \since Crypto++ 8.1
|
|
template<unsigned int C>
|
|
inline uint64x2_p VecShiftRight(const uint64x2_p vec)
|
|
{
|
|
const uint64x2_p m = {C, C};
|
|
return vec_sr(vec, m);
|
|
}
|
|
|
|
#endif // ARCH_PWR8
|
|
|
|
//@}
|
|
|
|
/// \name OTHER OPERATIONS
|
|
//@{
|
|
|
|
/// \brief Merge two vectors
|
|
/// \tparam T vector type
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \return vector
|
|
/// \par Wraps
|
|
/// vec_mergel
|
|
/// \since Crypto++ 8.1
|
|
template <class T>
|
|
inline T VecMergeLow(const T vec1, const T vec2)
|
|
{
|
|
return vec_mergel(vec1, vec2);
|
|
}
|
|
|
|
/// \brief Merge two vectors
|
|
/// \tparam T vector type
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \return vector
|
|
/// \par Wraps
|
|
/// vec_mergeh
|
|
/// \since Crypto++ 8.1
|
|
template <class T>
|
|
inline T VecMergeHigh(const T vec1, const T vec2)
|
|
{
|
|
return vec_mergeh(vec1, vec2);
|
|
}
|
|
|
|
/// \brief Broadcast 32-bit word to a vector
|
|
/// \param val the 32-bit value
|
|
/// \return vector
|
|
/// \par Wraps
|
|
/// vec_splats
|
|
/// \since Crypto++ 8.3
|
|
inline uint32x4_p VecSplatWord(word32 val)
|
|
{
|
|
// Fix spurious GCC warning???
|
|
CRYPTOPP_UNUSED(val);
|
|
|
|
// Apple Altivec and XL C++ do not offer vec_splats.
|
|
// GCC offers vec_splats back to -mcpu=power4.
|
|
#if defined(_ARCH_PWR4) && defined(__GNUC__)
|
|
return vec_splats(val);
|
|
#else
|
|
//const word32 x[4] = {val,val,val,val};
|
|
//return VecLoad(x);
|
|
const word32 x[4] = {val};
|
|
return vec_splat(VecLoad(x),0);
|
|
#endif
|
|
}
|
|
|
|
/// \brief Broadcast 32-bit element to a vector
|
|
/// \tparam the element number
|
|
/// \param val the 32-bit value
|
|
/// \return vector
|
|
/// \par Wraps
|
|
/// vec_splat
|
|
/// \since Crypto++ 8.3
|
|
template <unsigned int N>
|
|
inline uint32x4_p VecSplatElement(const uint32x4_p val)
|
|
{
|
|
return vec_splat(val, N);
|
|
}
|
|
|
|
#if defined(__VSX__) || defined(_ARCH_PWR8) || defined(CRYPTOPP_DOXYGEN_PROCESSING)
|
|
/// \brief Broadcast 64-bit double word to a vector
|
|
/// \param val the 64-bit value
|
|
/// \return vector
|
|
/// \par Wraps
|
|
/// vec_splats
|
|
/// \since Crypto++ 8.3
|
|
inline uint64x2_p VecSplatWord(word64 val)
|
|
{
|
|
// The PPC64 ABI says so.
|
|
return vec_splats((unsigned long long)val);
|
|
}
|
|
|
|
/// \brief Broadcast 64-bit element to a vector
|
|
/// \tparam the element number
|
|
/// \param val the 64-bit value
|
|
/// \return vector
|
|
/// \par Wraps
|
|
/// vec_splat
|
|
/// \since Crypto++ 8.3
|
|
template <unsigned int N>
|
|
inline uint64x2_p VecSplatElement(const uint64x2_p val)
|
|
{
|
|
#if defined(__VSX__) || defined(_ARCH_PWR8)
|
|
return vec_splat(val, N);
|
|
#else
|
|
enum {E=N&1};
|
|
if (E == 0)
|
|
{
|
|
const uint8x16_p m = {0,1,2,3, 4,5,6,7, 0,1,2,3, 4,5,6,7};
|
|
return vec_perm(val, val, m);
|
|
}
|
|
else // (E == 1)
|
|
{
|
|
const uint8x16_p m = {8,9,10,11, 12,13,14,15, 8,9,10,11, 12,13,14,15};
|
|
return vec_perm(val, val, m);
|
|
}
|
|
#endif
|
|
}
|
|
#endif
|
|
|
|
/// \brief Extract a dword from a vector
|
|
/// \tparam T vector type
|
|
/// \param val the vector
|
|
/// \return vector created from low dword
|
|
/// \details VecGetLow() extracts the low dword from a vector. The low dword
|
|
/// is composed of the least significant bits and occupies bytes 8 through 15
|
|
/// when viewed as a big endian array. The return vector is the same type as
|
|
/// the original vector and padded with 0's in the most significant bit positions.
|
|
/// \par Wraps
|
|
/// vec_sld
|
|
/// \since Crypto++ 7.0
|
|
template <class T>
|
|
inline T VecGetLow(const T val)
|
|
{
|
|
#if defined(CRYPTOPP_BIG_ENDIAN) && (defined(__VSX__) || defined(_ARCH_PWR8))
|
|
const T zero = {0};
|
|
return (T)VecMergeLow((uint64x2_p)zero, (uint64x2_p)val);
|
|
#else
|
|
return VecShiftRightOctet<8>(VecShiftLeftOctet<8>(val));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Extract a dword from a vector
|
|
/// \tparam T vector type
|
|
/// \param val the vector
|
|
/// \return vector created from high dword
|
|
/// \details VecGetHigh() extracts the high dword from a vector. The high dword
|
|
/// is composed of the most significant bits and occupies bytes 0 through 7
|
|
/// when viewed as a big endian array. The return vector is the same type as
|
|
/// the original vector and padded with 0's in the most significant bit positions.
|
|
/// \par Wraps
|
|
/// vec_sld
|
|
/// \since Crypto++ 7.0
|
|
template <class T>
|
|
inline T VecGetHigh(const T val)
|
|
{
|
|
#if defined(CRYPTOPP_BIG_ENDIAN) && (defined(__VSX__) || defined(_ARCH_PWR8))
|
|
const T zero = {0};
|
|
return (T)VecMergeHigh((uint64x2_p)zero, (uint64x2_p)val);
|
|
#else
|
|
return VecShiftRightOctet<8>(val);
|
|
#endif
|
|
}
|
|
|
|
/// \brief Exchange high and low double words
|
|
/// \tparam T vector type
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \par Wraps
|
|
/// vec_sld
|
|
/// \since Crypto++ 7.0
|
|
template <class T>
|
|
inline T VecSwapWords(const T vec)
|
|
{
|
|
return (T)vec_sld((uint8x16_p)vec, (uint8x16_p)vec, 8);
|
|
}
|
|
|
|
//@}
|
|
|
|
/// \name COMPARISON
|
|
//@{
|
|
|
|
/// \brief Compare two vectors
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \return true if vec1 equals vec2, false otherwise
|
|
/// \details VecEqual() performs a bitwise compare. The vector element types do
|
|
/// not matter.
|
|
/// \par Wraps
|
|
/// vec_all_eq
|
|
/// \since Crypto++ 8.0
|
|
template <class T1, class T2>
|
|
inline bool VecEqual(const T1 vec1, const T2 vec2)
|
|
{
|
|
return 1 == vec_all_eq((uint32x4_p)vec1, (uint32x4_p)vec2);
|
|
}
|
|
|
|
/// \brief Compare two vectors
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \return true if vec1 does not equal vec2, false otherwise
|
|
/// \details VecNotEqual() performs a bitwise compare. The vector element types do
|
|
/// not matter.
|
|
/// \par Wraps
|
|
/// vec_all_eq
|
|
/// \since Crypto++ 8.0
|
|
template <class T1, class T2>
|
|
inline bool VecNotEqual(const T1 vec1, const T2 vec2)
|
|
{
|
|
return 0 == vec_all_eq((uint32x4_p)vec1, (uint32x4_p)vec2);
|
|
}
|
|
|
|
//@}
|
|
|
|
////////////////// 32-bit Altivec /////////////////
|
|
|
|
/// \name 32-BIT ALTIVEC
|
|
//@{
|
|
|
|
/// \brief Add two vectors as if uint64x2_p
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \return vector
|
|
/// \details VecAdd64() performs <tt>vec1 + vec2</tt>. VecAdd64() performs as
|
|
/// if adding two uint64x2_p vectors. On POWER7 and below VecAdd64() manages
|
|
/// the carries from the elements.
|
|
/// \par Wraps
|
|
/// vec_add for POWER8, vec_addc, vec_perm, vec_add for Altivec
|
|
/// \since Crypto++ 8.3
|
|
inline uint32x4_p VecAdd64(const uint32x4_p& vec1, const uint32x4_p& vec2)
|
|
{
|
|
// 64-bit elements available at POWER7 with VSX, but addudm requires POWER8
|
|
#if defined(_ARCH_PWR8) && !defined(CRYPTOPP_DEBUG)
|
|
return (uint32x4_p)vec_add((uint64x2_p)vec1, (uint64x2_p)vec2);
|
|
#else
|
|
// The carry mask selects carrys for elements 1 and 3 and sets
|
|
// remaining elements to 0. The results is then shifted so the
|
|
// carried values are added to elements 0 and 2.
|
|
#if defined(CRYPTOPP_BIG_ENDIAN)
|
|
const uint32x4_p zero = {0, 0, 0, 0};
|
|
const uint32x4_p mask = {0, 1, 0, 1};
|
|
#else
|
|
const uint32x4_p zero = {0, 0, 0, 0};
|
|
const uint32x4_p mask = {1, 0, 1, 0};
|
|
#endif
|
|
|
|
uint32x4_p cy = vec_addc(vec1, vec2);
|
|
uint32x4_p res = vec_add(vec1, vec2);
|
|
cy = vec_and(mask, cy);
|
|
cy = vec_sld (cy, zero, 4);
|
|
return vec_add(res, cy);
|
|
#endif
|
|
}
|
|
|
|
#if defined(_ARCH_PWR8) || defined(CRYPTOPP_DOXYGEN_PROCESSING)
|
|
/// \brief Add two vectors as if uint64x2_p
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \return vector
|
|
/// \details VecAdd64() performs <tt>vec1 + vec2</tt>. VecAdd64() performs as
|
|
/// if adding two uint64x2_p vectors. On POWER7 and below VecAdd64() manages
|
|
/// the carries from the elements.
|
|
/// \par Wraps
|
|
/// vec_add for POWER8
|
|
/// \since Crypto++ 8.3
|
|
inline uint64x2_p VecAdd64(const uint64x2_p& vec1, const uint64x2_p& vec2)
|
|
{
|
|
// 64-bit elements available at POWER7 with VSX, but addudm requires POWER8
|
|
const uint64x2_p res = vec_add(vec1, vec2);
|
|
|
|
#if defined(CRYPTOPP_DEBUG)
|
|
// Test 32-bit add in debug builds while we are here.
|
|
const uint32x4_p x = (uint32x4_p)vec1;
|
|
const uint32x4_p y = (uint32x4_p)vec2;
|
|
const uint32x4_p r = VecAdd64(x, y);
|
|
|
|
CRYPTOPP_ASSERT(vec_all_eq((uint32x4_p)res, r) == 1);
|
|
#endif
|
|
|
|
return res;
|
|
}
|
|
#endif
|
|
|
|
/// \brief Subtract two vectors as if uint64x2_p
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \details VecSub64() performs <tt>vec1 - vec2</tt>. VecSub64() performs as
|
|
/// if subtracting two uint64x2_p vectors. On POWER7 and below VecSub64()
|
|
/// manages the borrows from the elements.
|
|
/// \par Wraps
|
|
/// vec_sub for POWER8, vec_subc, vec_andc, vec_perm, vec_sub for Altivec
|
|
/// \since Crypto++ 8.3
|
|
inline uint32x4_p VecSub64(const uint32x4_p& vec1, const uint32x4_p& vec2)
|
|
{
|
|
#if defined(_ARCH_PWR8) && !defined(CRYPTOPP_DEBUG)
|
|
// 64-bit elements available at POWER7 with VSX, but subudm requires POWER8
|
|
return (uint32x4_p)vec_sub((uint64x2_p)vec1, (uint64x2_p)vec2);
|
|
#else
|
|
// The borrow mask selects borrows for elements 1 and 3 and sets
|
|
// remaining elements to 0. The results is then shifted so the
|
|
// borrowed values are subtracted from elements 0 and 2.
|
|
#if defined(CRYPTOPP_BIG_ENDIAN)
|
|
const uint32x4_p zero = {0, 0, 0, 0};
|
|
const uint32x4_p mask = {0, 1, 0, 1};
|
|
#else
|
|
const uint32x4_p zero = {0, 0, 0, 0};
|
|
const uint32x4_p mask = {1, 0, 1, 0};
|
|
#endif
|
|
|
|
// subc sets the complement of borrow, so we have to
|
|
// un-complement it using andc.
|
|
uint32x4_p bw = vec_subc(vec1, vec2);
|
|
uint32x4_p res = vec_sub(vec1, vec2);
|
|
bw = vec_andc(mask, bw);
|
|
bw = vec_sld (bw, zero, 4);
|
|
return vec_sub(res, bw);
|
|
#endif
|
|
}
|
|
|
|
#if defined(_ARCH_PWR8) || defined(CRYPTOPP_DOXYGEN_PROCESSING)
|
|
/// \brief Subtract two vectors as if uint64x2_p
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \details VecSub64() performs <tt>vec1 - vec2</tt>. VecSub64() performs as
|
|
/// if subtracting two uint64x2_p vectors. On POWER7 and below VecSub64()
|
|
/// manages the borrows from the elements.
|
|
/// \par Wraps
|
|
/// vec_sub for POWER8
|
|
/// \since Crypto++ 8.3
|
|
inline uint64x2_p VecSub64(const uint64x2_p& vec1, const uint64x2_p& vec2)
|
|
{
|
|
// 64-bit elements available at POWER7 with VSX, but subudm requires POWER8
|
|
const uint64x2_p res = vec_sub(vec1, vec2);
|
|
|
|
#if defined(CRYPTOPP_DEBUG)
|
|
// Test 32-bit sub in debug builds while we are here.
|
|
const uint32x4_p x = (uint32x4_p)vec1;
|
|
const uint32x4_p y = (uint32x4_p)vec2;
|
|
const uint32x4_p r = VecSub64(x, y);
|
|
|
|
CRYPTOPP_ASSERT(vec_all_eq((uint32x4_p)res, r) == 1);
|
|
#endif
|
|
|
|
return res;
|
|
}
|
|
#endif
|
|
|
|
/// \brief Rotate a vector left as if uint64x2_p
|
|
/// \tparam C rotate bit count
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecRotateLeft() rotates each element in a vector by bit count.
|
|
/// vec is rotated as if uint64x2_p.
|
|
/// \par Wraps
|
|
/// vec_rl
|
|
/// \since Crypto++ 8.3
|
|
template<unsigned int C>
|
|
inline uint32x4_p VecRotateLeft64(const uint32x4_p vec)
|
|
{
|
|
#if defined(_ARCH_PWR8) && !defined(CRYPTOPP_DEBUG)
|
|
// 64-bit elements available at POWER7 with VSX, but vec_rl and vec_sl require POWER8
|
|
return (uint32x4_p)VecRotateLeft<C>((uint64x2_p)vec);
|
|
#else
|
|
// C=0, 32, or 64 needs special handling. That is S32 and S64 below.
|
|
enum {S64=C&63, S32=C&31, BR=(S64>=32)};
|
|
|
|
// Get the low bits, shift them to high bits
|
|
uint32x4_p t1 = VecShiftLeft<S32>(vec);
|
|
// Get the high bits, shift them to low bits
|
|
uint32x4_p t2 = VecShiftRight<32-S32>(vec);
|
|
|
|
if (S64 == 0)
|
|
{
|
|
const uint8x16_p m = {0,1,2,3, 4,5,6,7, 8,9,10,11, 12,13,14,15};
|
|
return VecPermute(vec, m);
|
|
}
|
|
else if (S64 == 32)
|
|
{
|
|
const uint8x16_p m = {4,5,6,7, 0,1,2,3, 12,13,14,15, 8,9,10,11};
|
|
return VecPermute(vec, m);
|
|
}
|
|
else if (BR) // Big rotate amount?
|
|
{
|
|
const uint8x16_p m = {4,5,6,7, 0,1,2,3, 12,13,14,15, 8,9,10,11};
|
|
t1 = VecPermute(t1, m);
|
|
}
|
|
else
|
|
{
|
|
const uint8x16_p m = {4,5,6,7, 0,1,2,3, 12,13,14,15, 8,9,10,11};
|
|
t2 = VecPermute(t2, m);
|
|
}
|
|
|
|
return vec_or(t1, t2);
|
|
#endif
|
|
}
|
|
|
|
/// \brief Rotate a vector left as if uint64x2_p
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecRotateLeft<8>() rotates each element in a vector
|
|
/// by 8-bits. vec is rotated as if uint64x2_p. This specialization
|
|
/// is used by algorithms like Speck128.
|
|
/// \par Wraps
|
|
/// vec_rl
|
|
/// \since Crypto++ 8.3
|
|
template<>
|
|
inline uint32x4_p VecRotateLeft64<8>(const uint32x4_p vec)
|
|
{
|
|
#if (CRYPTOPP_BIG_ENDIAN)
|
|
const uint8x16_p m = { 1,2,3,4, 5,6,7,0, 9,10,11,12, 13,14,15,8 };
|
|
return VecPermute(vec, m);
|
|
#else
|
|
const uint8x16_p m = { 7,0,1,2, 3,4,5,6, 15,8,9,10, 11,12,13,14 };
|
|
return VecPermute(vec, m);
|
|
#endif
|
|
}
|
|
|
|
#if defined(_ARCH_PWR8) || defined(CRYPTOPP_DOXYGEN_PROCESSING)
|
|
/// \brief Rotate a vector left as if uint64x2_p
|
|
/// \tparam C rotate bit count
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecRotateLeft64() rotates each element in a vector by
|
|
/// bit count. vec is rotated as if uint64x2_p.
|
|
/// \par Wraps
|
|
/// vec_rl
|
|
/// \since Crypto++ 8.3
|
|
template<unsigned int C>
|
|
inline uint64x2_p VecRotateLeft64(const uint64x2_p vec)
|
|
{
|
|
// 64-bit elements available at POWER7 with VSX, but vec_rl and vec_sl require POWER8
|
|
const uint64x2_p res = VecRotateLeft<C>(vec);
|
|
|
|
#if defined(CRYPTOPP_DEBUG)
|
|
// Test 32-bit rotate in debug builds while we are here.
|
|
const uint32x4_p x = (uint32x4_p)vec;
|
|
const uint32x4_p r = VecRotateLeft64<C>(x);
|
|
|
|
CRYPTOPP_ASSERT(vec_all_eq((uint32x4_p)res, r) == 1);
|
|
#endif
|
|
|
|
return res;
|
|
}
|
|
#endif
|
|
|
|
/// \brief Rotate a vector right as if uint64x2_p
|
|
/// \tparam C rotate bit count
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecRotateRight64() rotates each element in a vector by
|
|
/// bit count. vec is rotated as if uint64x2_p.
|
|
/// \par Wraps
|
|
/// vec_rl
|
|
/// \since Crypto++ 8.3
|
|
template<unsigned int C>
|
|
inline uint32x4_p VecRotateRight64(const uint32x4_p vec)
|
|
{
|
|
#if defined(_ARCH_PWR8) && !defined(CRYPTOPP_DEBUG)
|
|
// 64-bit elements available at POWER7 with VSX, but vec_rl and vec_sl require POWER8
|
|
return (uint32x4_p)VecRotateRight<C>((uint64x2_p)vec);
|
|
#else
|
|
// C=0, 32, or 64 needs special handling. That is S32 and S64 below.
|
|
enum {S64=C&63, S32=C&31, BR=(S64>=32)};
|
|
|
|
// Get the low bits, shift them to high bits
|
|
uint32x4_p t1 = VecShiftRight<S32>(vec);
|
|
// Get the high bits, shift them to low bits
|
|
uint32x4_p t2 = VecShiftLeft<32-S32>(vec);
|
|
|
|
if (S64 == 0)
|
|
{
|
|
const uint8x16_p m = {0,1,2,3, 4,5,6,7, 8,9,10,11, 12,13,14,15};
|
|
return VecPermute(vec, m);
|
|
}
|
|
else if (S64 == 32)
|
|
{
|
|
const uint8x16_p m = {4,5,6,7, 0,1,2,3, 12,13,14,15, 8,9,10,11};
|
|
return VecPermute(vec, m);
|
|
}
|
|
else if (BR) // Big rotate amount?
|
|
{
|
|
const uint8x16_p m = {4,5,6,7, 0,1,2,3, 12,13,14,15, 8,9,10,11};
|
|
t1 = VecPermute(t1, m);
|
|
}
|
|
else
|
|
{
|
|
const uint8x16_p m = {4,5,6,7, 0,1,2,3, 12,13,14,15, 8,9,10,11};
|
|
t2 = VecPermute(t2, m);
|
|
}
|
|
|
|
return vec_or(t1, t2);
|
|
#endif
|
|
}
|
|
|
|
/// \brief Rotate a vector right as if uint64x2_p
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecRotateRight64<8>() rotates each element in a vector
|
|
/// by 8-bits. vec is rotated as if uint64x2_p. This specialization
|
|
/// is used by algorithms like Speck128.
|
|
/// \details vec is rotated as if uint64x2_p.
|
|
/// \par Wraps
|
|
/// vec_rl
|
|
/// \since Crypto++ 8.3
|
|
template<>
|
|
inline uint32x4_p VecRotateRight64<8>(const uint32x4_p vec)
|
|
{
|
|
#if (CRYPTOPP_BIG_ENDIAN)
|
|
const uint8x16_p m = { 7,0,1,2, 3,4,5,6, 15,8,9,10, 11,12,13,14 };
|
|
return VecPermute(vec, m);
|
|
#else
|
|
const uint8x16_p m = { 1,2,3,4, 5,6,7,0, 9,10,11,12, 13,14,15,8 };
|
|
return VecPermute(vec, m);
|
|
#endif
|
|
}
|
|
|
|
#if defined(__VSX__) || defined(_ARCH_PWR8) || defined(CRYPTOPP_DOXYGEN_PROCESSING)
|
|
/// \brief Rotate a vector right as if uint64x2_p
|
|
/// \tparam C rotate bit count
|
|
/// \param vec the vector
|
|
/// \return vector
|
|
/// \details VecRotateRight64() rotates each element in a vector by
|
|
/// bit count. vec is rotated as if uint64x2_p.
|
|
/// \par Wraps
|
|
/// vec_rl
|
|
/// \since Crypto++ 8.3
|
|
template<unsigned int C>
|
|
inline uint64x2_p VecRotateRight64(const uint64x2_p vec)
|
|
{
|
|
// 64-bit elements available at POWER7 with VSX, but vec_rl and vec_sl require POWER8
|
|
const uint64x2_p res = VecRotateRight<C>(vec);
|
|
|
|
#if defined(CRYPTOPP_DEBUG)
|
|
// Test 32-bit rotate in debug builds while we are here.
|
|
const uint32x4_p x = (uint32x4_p)vec;
|
|
const uint32x4_p r = VecRotateRight64<C>(x);
|
|
|
|
CRYPTOPP_ASSERT(vec_all_eq((uint32x4_p)res, r) == 1);
|
|
#endif
|
|
|
|
return res;
|
|
}
|
|
#endif
|
|
|
|
/// \brief AND two vectors as if uint64x2_p
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \return vector
|
|
/// \details VecAnd64() performs <tt>vec1 & vec2</tt>.
|
|
/// vec2 is cast to the same type as vec1. The return vector
|
|
/// is the same type as vec1.
|
|
/// \details VecAnd64() is a convenience function that simply performs a VecAnd().
|
|
/// \par Wraps
|
|
/// vec_and
|
|
/// \since Crypto++ 8.3
|
|
template <class T1, class T2>
|
|
inline T1 VecAnd64(const T1 vec1, const T2 vec2)
|
|
{
|
|
return (T1)vec_and(vec1, (T1)vec2);
|
|
}
|
|
|
|
/// \brief OR two vectors as if uint64x2_p
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \return vector
|
|
/// \details VecOr64() performs <tt>vec1 | vec2</tt>.
|
|
/// vec2 is cast to the same type as vec1. The return vector
|
|
/// is the same type as vec1.
|
|
/// \details VecOr64() is a convenience function that simply performs a VecOr().
|
|
/// \par Wraps
|
|
/// vec_or
|
|
/// \since Crypto++ 8.3
|
|
template <class T1, class T2>
|
|
inline T1 VecOr64(const T1 vec1, const T2 vec2)
|
|
{
|
|
return (T1)vec_or(vec1, (T1)vec2);
|
|
}
|
|
|
|
/// \brief XOR two vectors as if uint64x2_p
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param vec1 the first vector
|
|
/// \param vec2 the second vector
|
|
/// \return vector
|
|
/// \details VecXor64() performs <tt>vec1 ^ vec2</tt>.
|
|
/// vec2 is cast to the same type as vec1. The return vector
|
|
/// is the same type as vec1.
|
|
/// \details VecXor64() is a convenience function that simply performs a VecXor().
|
|
/// \par Wraps
|
|
/// vec_xor
|
|
/// \since Crypto++ 8.3
|
|
template <class T1, class T2>
|
|
inline T1 VecXor64(const T1 vec1, const T2 vec2)
|
|
{
|
|
return (T1)vec_xor(vec1, (T1)vec2);
|
|
}
|
|
|
|
/// \brief Broadcast 64-bit double word to a vector
|
|
/// \param val the 64-bit value
|
|
/// \return vector
|
|
/// \par Wraps
|
|
/// vec_splats
|
|
/// \since Crypto++ 8.3
|
|
inline uint32x4_p VecSplatWord64(word64 val)
|
|
{
|
|
#if defined(_ARCH_PWR8)
|
|
// The PPC64 ABI says so.
|
|
return (uint32x4_p)vec_splats((unsigned long long)val);
|
|
#else
|
|
const word64 x[2] = {val,val};
|
|
return (uint32x4_p)VecLoad((const word32*)x);
|
|
#endif
|
|
}
|
|
|
|
/// \brief Broadcast 64-bit element to a vector as if uint64x2_p
|
|
/// \tparam the element number
|
|
/// \param val the 64-bit value
|
|
/// \return vector
|
|
/// \par Wraps
|
|
/// vec_splat
|
|
/// \since Crypto++ 8.3
|
|
template <unsigned int N>
|
|
inline uint32x4_p VecSplatElement64(const uint32x4_p val)
|
|
{
|
|
#if defined(__VSX__) || defined(_ARCH_PWR8)
|
|
return (uint32x4_p)vec_splat((uint64x2_p)val, N);
|
|
#else
|
|
enum {E=N&1};
|
|
if (E == 0)
|
|
{
|
|
const uint8x16_p m = {0,1,2,3, 4,5,6,7, 0,1,2,3, 4,5,6,7};
|
|
return (uint32x4_p)vec_perm(val, val, m);
|
|
}
|
|
else // (E == 1)
|
|
{
|
|
const uint8x16_p m = {8,9,10,11, 12,13,14,15, 8,9,10,11, 12,13,14,15};
|
|
return (uint32x4_p)vec_perm(val, val, m);
|
|
}
|
|
#endif
|
|
}
|
|
|
|
#if defined(__VSX__) || defined(_ARCH_PWR8) || defined(CRYPTOPP_DOXYGEN_PROCESSING)
|
|
/// \brief Broadcast 64-bit element to a vector
|
|
/// \tparam the element number
|
|
/// \param val the 64-bit value
|
|
/// \return vector
|
|
/// \since Crypto++ 8.3
|
|
template <unsigned int N>
|
|
inline uint64x2_p VecSplatElement64(const uint64x2_p val)
|
|
{
|
|
return vec_splat(val, N);
|
|
}
|
|
#endif
|
|
|
|
//@}
|
|
|
|
//////////////////////// Power8 Crypto ////////////////////////
|
|
|
|
// __CRYPTO__ alone is not enough. Clang will define __CRYPTO__
|
|
// when it is not available, like with Power7. Sigh...
|
|
#if (defined(_ARCH_PWR8) && defined(__CRYPTO__)) || defined(CRYPTOPP_DOXYGEN_PROCESSING)
|
|
|
|
/// \name POLYNOMIAL MULTIPLICATION
|
|
//@{
|
|
|
|
/// \brief Polynomial multiplication
|
|
/// \param a the first term
|
|
/// \param b the second term
|
|
/// \return vector product
|
|
/// \details VecPolyMultiply() performs polynomial multiplication. POWER8
|
|
/// polynomial multiplication multiplies the high and low terms, and then
|
|
/// XOR's the high and low products. That is, the result is <tt>ah*bh XOR
|
|
/// al*bl</tt>. It is different behavior than Intel polynomial
|
|
/// multiplication. To obtain a single product without the XOR, then set
|
|
/// one of the high or low terms to 0. For example, setting <tt>ah=0</tt>
|
|
/// results in <tt>0*bh XOR al*bl = al*bl</tt>.
|
|
/// \par Wraps
|
|
/// __vpmsumw, __builtin_altivec_crypto_vpmsumw and __builtin_crypto_vpmsumw.
|
|
/// \since Crypto++ 8.1
|
|
inline uint32x4_p VecPolyMultiply(const uint32x4_p& a, const uint32x4_p& b)
|
|
{
|
|
#if defined(__ibmxl__) || (defined(_AIX) && defined(__xlC__))
|
|
return __vpmsumw (a, b);
|
|
#elif defined(__clang__)
|
|
return __builtin_altivec_crypto_vpmsumw (a, b);
|
|
#else
|
|
return __builtin_crypto_vpmsumw (a, b);
|
|
#endif
|
|
}
|
|
|
|
/// \brief Polynomial multiplication
|
|
/// \param a the first term
|
|
/// \param b the second term
|
|
/// \return vector product
|
|
/// \details VecPolyMultiply() performs polynomial multiplication. POWER8
|
|
/// polynomial multiplication multiplies the high and low terms, and then
|
|
/// XOR's the high and low products. That is, the result is <tt>ah*bh XOR
|
|
/// al*bl</tt>. It is different behavior than Intel polynomial
|
|
/// multiplication. To obtain a single product without the XOR, then set
|
|
/// one of the high or low terms to 0. For example, setting <tt>ah=0</tt>
|
|
/// results in <tt>0*bh XOR al*bl = al*bl</tt>.
|
|
/// \par Wraps
|
|
/// __vpmsumd, __builtin_altivec_crypto_vpmsumd and __builtin_crypto_vpmsumd.
|
|
/// \since Crypto++ 8.1
|
|
inline uint64x2_p VecPolyMultiply(const uint64x2_p& a, const uint64x2_p& b)
|
|
{
|
|
#if defined(__ibmxl__) || (defined(_AIX) && defined(__xlC__))
|
|
return __vpmsumd (a, b);
|
|
#elif defined(__clang__)
|
|
return __builtin_altivec_crypto_vpmsumd (a, b);
|
|
#else
|
|
return __builtin_crypto_vpmsumd (a, b);
|
|
#endif
|
|
}
|
|
|
|
/// \brief Polynomial multiplication
|
|
/// \param a the first term
|
|
/// \param b the second term
|
|
/// \return vector product
|
|
/// \details VecIntelMultiply00() performs polynomial multiplication and presents
|
|
/// the result like Intel's <tt>c = _mm_clmulepi64_si128(a, b, 0x00)</tt>.
|
|
/// The <tt>0x00</tt> indicates the low 64-bits of <tt>a</tt> and <tt>b</tt>
|
|
/// are multiplied.
|
|
/// \note An Intel XMM register is composed of 128-bits. The leftmost bit
|
|
/// is MSB and numbered 127, while the rightmost bit is LSB and numbered 0.
|
|
/// \par Wraps
|
|
/// __vpmsumd, __builtin_altivec_crypto_vpmsumd and __builtin_crypto_vpmsumd.
|
|
/// \since Crypto++ 8.0
|
|
inline uint64x2_p VecIntelMultiply00(const uint64x2_p& a, const uint64x2_p& b)
|
|
{
|
|
#if defined(CRYPTOPP_BIG_ENDIAN)
|
|
return VecSwapWords(VecPolyMultiply(VecGetHigh(a), VecGetHigh(b)));
|
|
#else
|
|
return VecPolyMultiply(VecGetHigh(a), VecGetHigh(b));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Polynomial multiplication
|
|
/// \param a the first term
|
|
/// \param b the second term
|
|
/// \return vector product
|
|
/// \details VecIntelMultiply01 performs() polynomial multiplication and presents
|
|
/// the result like Intel's <tt>c = _mm_clmulepi64_si128(a, b, 0x01)</tt>.
|
|
/// The <tt>0x01</tt> indicates the low 64-bits of <tt>a</tt> and high
|
|
/// 64-bits of <tt>b</tt> are multiplied.
|
|
/// \note An Intel XMM register is composed of 128-bits. The leftmost bit
|
|
/// is MSB and numbered 127, while the rightmost bit is LSB and numbered 0.
|
|
/// \par Wraps
|
|
/// __vpmsumd, __builtin_altivec_crypto_vpmsumd and __builtin_crypto_vpmsumd.
|
|
/// \since Crypto++ 8.0
|
|
inline uint64x2_p VecIntelMultiply01(const uint64x2_p& a, const uint64x2_p& b)
|
|
{
|
|
#if defined(CRYPTOPP_BIG_ENDIAN)
|
|
return VecSwapWords(VecPolyMultiply(a, VecGetHigh(b)));
|
|
#else
|
|
return VecPolyMultiply(a, VecGetHigh(b));
|
|
#endif
|
|
}
|
|
|
|
/// \brief Polynomial multiplication
|
|
/// \param a the first term
|
|
/// \param b the second term
|
|
/// \return vector product
|
|
/// \details VecIntelMultiply10() performs polynomial multiplication and presents
|
|
/// the result like Intel's <tt>c = _mm_clmulepi64_si128(a, b, 0x10)</tt>.
|
|
/// The <tt>0x10</tt> indicates the high 64-bits of <tt>a</tt> and low
|
|
/// 64-bits of <tt>b</tt> are multiplied.
|
|
/// \note An Intel XMM register is composed of 128-bits. The leftmost bit
|
|
/// is MSB and numbered 127, while the rightmost bit is LSB and numbered 0.
|
|
/// \par Wraps
|
|
/// __vpmsumd, __builtin_altivec_crypto_vpmsumd and __builtin_crypto_vpmsumd.
|
|
/// \since Crypto++ 8.0
|
|
inline uint64x2_p VecIntelMultiply10(const uint64x2_p& a, const uint64x2_p& b)
|
|
{
|
|
#if defined(CRYPTOPP_BIG_ENDIAN)
|
|
return VecSwapWords(VecPolyMultiply(VecGetHigh(a), b));
|
|
#else
|
|
return VecPolyMultiply(VecGetHigh(a), b);
|
|
#endif
|
|
}
|
|
|
|
/// \brief Polynomial multiplication
|
|
/// \param a the first term
|
|
/// \param b the second term
|
|
/// \return vector product
|
|
/// \details VecIntelMultiply11() performs polynomial multiplication and presents
|
|
/// the result like Intel's <tt>c = _mm_clmulepi64_si128(a, b, 0x11)</tt>.
|
|
/// The <tt>0x11</tt> indicates the high 64-bits of <tt>a</tt> and <tt>b</tt>
|
|
/// are multiplied.
|
|
/// \note An Intel XMM register is composed of 128-bits. The leftmost bit
|
|
/// is MSB and numbered 127, while the rightmost bit is LSB and numbered 0.
|
|
/// \par Wraps
|
|
/// __vpmsumd, __builtin_altivec_crypto_vpmsumd and __builtin_crypto_vpmsumd.
|
|
/// \since Crypto++ 8.0
|
|
inline uint64x2_p VecIntelMultiply11(const uint64x2_p& a, const uint64x2_p& b)
|
|
{
|
|
#if defined(CRYPTOPP_BIG_ENDIAN)
|
|
return VecSwapWords(VecPolyMultiply(VecGetLow(a), b));
|
|
#else
|
|
return VecPolyMultiply(VecGetLow(a), b);
|
|
#endif
|
|
}
|
|
|
|
//@}
|
|
|
|
/// \name AES ENCRYPTION
|
|
//@{
|
|
|
|
/// \brief One round of AES encryption
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param state the state vector
|
|
/// \param key the subkey vector
|
|
/// \details VecEncrypt() performs one round of AES encryption of state
|
|
/// using subkey key. The return vector is the same type as state.
|
|
/// \details VecEncrypt() is available on POWER8 and above.
|
|
/// \par Wraps
|
|
/// __vcipher, __builtin_altivec_crypto_vcipher, __builtin_crypto_vcipher
|
|
/// \since GCC and XLC since Crypto++ 6.0, LLVM Clang since Crypto++ 8.0
|
|
template <class T1, class T2>
|
|
inline T1 VecEncrypt(const T1 state, const T2 key)
|
|
{
|
|
#if defined(__ibmxl__) || (defined(_AIX) && defined(__xlC__))
|
|
return (T1)__vcipher((uint8x16_p)state, (uint8x16_p)key);
|
|
#elif defined(__clang__)
|
|
return (T1)__builtin_altivec_crypto_vcipher((uint64x2_p)state, (uint64x2_p)key);
|
|
#elif defined(__GNUC__)
|
|
return (T1)__builtin_crypto_vcipher((uint64x2_p)state, (uint64x2_p)key);
|
|
#else
|
|
CRYPTOPP_ASSERT(0);
|
|
#endif
|
|
}
|
|
|
|
/// \brief Final round of AES encryption
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param state the state vector
|
|
/// \param key the subkey vector
|
|
/// \details VecEncryptLast() performs the final round of AES encryption
|
|
/// of state using subkey key. The return vector is the same type as state.
|
|
/// \details VecEncryptLast() is available on POWER8 and above.
|
|
/// \par Wraps
|
|
/// __vcipherlast, __builtin_altivec_crypto_vcipherlast, __builtin_crypto_vcipherlast
|
|
/// \since GCC and XLC since Crypto++ 6.0, LLVM Clang since Crypto++ 8.0
|
|
template <class T1, class T2>
|
|
inline T1 VecEncryptLast(const T1 state, const T2 key)
|
|
{
|
|
#if defined(__ibmxl__) || (defined(_AIX) && defined(__xlC__))
|
|
return (T1)__vcipherlast((uint8x16_p)state, (uint8x16_p)key);
|
|
#elif defined(__clang__)
|
|
return (T1)__builtin_altivec_crypto_vcipherlast((uint64x2_p)state, (uint64x2_p)key);
|
|
#elif defined(__GNUC__)
|
|
return (T1)__builtin_crypto_vcipherlast((uint64x2_p)state, (uint64x2_p)key);
|
|
#else
|
|
CRYPTOPP_ASSERT(0);
|
|
#endif
|
|
}
|
|
|
|
/// \brief One round of AES decryption
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param state the state vector
|
|
/// \param key the subkey vector
|
|
/// \details VecDecrypt() performs one round of AES decryption of state
|
|
/// using subkey key. The return vector is the same type as state.
|
|
/// \details VecDecrypt() is available on POWER8 and above.
|
|
/// \par Wraps
|
|
/// __vncipher, __builtin_altivec_crypto_vncipher, __builtin_crypto_vncipher
|
|
/// \since GCC and XLC since Crypto++ 6.0, LLVM Clang since Crypto++ 8.0
|
|
template <class T1, class T2>
|
|
inline T1 VecDecrypt(const T1 state, const T2 key)
|
|
{
|
|
#if defined(__ibmxl__) || (defined(_AIX) && defined(__xlC__))
|
|
return (T1)__vncipher((uint8x16_p)state, (uint8x16_p)key);
|
|
#elif defined(__clang__)
|
|
return (T1)__builtin_altivec_crypto_vncipher((uint64x2_p)state, (uint64x2_p)key);
|
|
#elif defined(__GNUC__)
|
|
return (T1)__builtin_crypto_vncipher((uint64x2_p)state, (uint64x2_p)key);
|
|
#else
|
|
CRYPTOPP_ASSERT(0);
|
|
#endif
|
|
}
|
|
|
|
/// \brief Final round of AES decryption
|
|
/// \tparam T1 vector type
|
|
/// \tparam T2 vector type
|
|
/// \param state the state vector
|
|
/// \param key the subkey vector
|
|
/// \details VecDecryptLast() performs the final round of AES decryption
|
|
/// of state using subkey key. The return vector is the same type as state.
|
|
/// \details VecDecryptLast() is available on POWER8 and above.
|
|
/// \par Wraps
|
|
/// __vncipherlast, __builtin_altivec_crypto_vncipherlast, __builtin_crypto_vncipherlast
|
|
/// \since GCC and XLC since Crypto++ 6.0, LLVM Clang since Crypto++ 8.0
|
|
template <class T1, class T2>
|
|
inline T1 VecDecryptLast(const T1 state, const T2 key)
|
|
{
|
|
#if defined(__ibmxl__) || (defined(_AIX) && defined(__xlC__))
|
|
return (T1)__vncipherlast((uint8x16_p)state, (uint8x16_p)key);
|
|
#elif defined(__clang__)
|
|
return (T1)__builtin_altivec_crypto_vncipherlast((uint64x2_p)state, (uint64x2_p)key);
|
|
#elif defined(__GNUC__)
|
|
return (T1)__builtin_crypto_vncipherlast((uint64x2_p)state, (uint64x2_p)key);
|
|
#else
|
|
CRYPTOPP_ASSERT(0);
|
|
#endif
|
|
}
|
|
|
|
//@}
|
|
|
|
/// \name SHA DIGESTS
|
|
//@{
|
|
|
|
/// \brief SHA256 Sigma functions
|
|
/// \tparam func function
|
|
/// \tparam fmask function mask
|
|
/// \tparam T vector type
|
|
/// \param data the block to transform
|
|
/// \details VecSHA256() selects sigma0, sigma1, Sigma0, Sigma1 based on
|
|
/// func and fmask. The return vector is the same type as data.
|
|
/// \details VecSHA256() is available on POWER8 and above.
|
|
/// \par Wraps
|
|
/// __vshasigmaw, __builtin_altivec_crypto_vshasigmaw, __builtin_crypto_vshasigmaw
|
|
/// \since GCC and XLC since Crypto++ 6.0, LLVM Clang since Crypto++ 8.0
|
|
template <int func, int fmask, class T>
|
|
inline T VecSHA256(const T data)
|
|
{
|
|
#if defined(__ibmxl__) || (defined(_AIX) && defined(__xlC__))
|
|
return (T)__vshasigmaw((uint32x4_p)data, func, fmask);
|
|
#elif defined(__clang__)
|
|
return (T)__builtin_altivec_crypto_vshasigmaw((uint32x4_p)data, func, fmask);
|
|
#elif defined(__GNUC__)
|
|
return (T)__builtin_crypto_vshasigmaw((uint32x4_p)data, func, fmask);
|
|
#else
|
|
CRYPTOPP_ASSERT(0);
|
|
#endif
|
|
}
|
|
|
|
/// \brief SHA512 Sigma functions
|
|
/// \tparam func function
|
|
/// \tparam fmask function mask
|
|
/// \tparam T vector type
|
|
/// \param data the block to transform
|
|
/// \details VecSHA512() selects sigma0, sigma1, Sigma0, Sigma1 based on
|
|
/// func and fmask. The return vector is the same type as data.
|
|
/// \details VecSHA512() is available on POWER8 and above.
|
|
/// \par Wraps
|
|
/// __vshasigmad, __builtin_altivec_crypto_vshasigmad, __builtin_crypto_vshasigmad
|
|
/// \since GCC and XLC since Crypto++ 6.0, LLVM Clang since Crypto++ 8.0
|
|
template <int func, int fmask, class T>
|
|
inline T VecSHA512(const T data)
|
|
{
|
|
#if defined(__ibmxl__) || (defined(_AIX) && defined(__xlC__))
|
|
return (T)__vshasigmad((uint64x2_p)data, func, fmask);
|
|
#elif defined(__clang__)
|
|
return (T)__builtin_altivec_crypto_vshasigmad((uint64x2_p)data, func, fmask);
|
|
#elif defined(__GNUC__)
|
|
return (T)__builtin_crypto_vshasigmad((uint64x2_p)data, func, fmask);
|
|
#else
|
|
CRYPTOPP_ASSERT(0);
|
|
#endif
|
|
}
|
|
|
|
//@}
|
|
|
|
#endif // __CRYPTO__
|
|
|
|
#endif // _ALTIVEC_
|
|
|
|
NAMESPACE_END
|
|
|
|
#if CRYPTOPP_GCC_DIAGNOSTIC_AVAILABLE
|
|
# pragma GCC diagnostic pop
|
|
#endif
|
|
|
|
#endif // CRYPTOPP_PPC_CRYPTO_H
|