/* * Lightweight wrappers around AltiVec for 32-bit operations * (C) 2009 Jack Lloyd * * Distributed under the terms of the Botan license */ #ifndef BOTAN_SIMD_ALTIVEC_H__ #define BOTAN_SIMD_ALTIVEC_H__ #if defined(BOTAN_TARGET_CPU_HAS_ALTIVEC) #include #include #include #undef vector #undef bool namespace Botan { class SIMD_Altivec { public: static bool enabled() { return CPUID::has_altivec(); } SIMD_Altivec(const u32bit B[4]) { reg = (__vector unsigned int){B[0], B[1], B[2], B[3]}; } SIMD_Altivec(u32bit B0, u32bit B1, u32bit B2, u32bit B3) { reg = (__vector unsigned int){B0, B1, B2, B3}; } SIMD_Altivec(u32bit B) { reg = (__vector unsigned int){B, B, B, B}; } static SIMD_Altivec load_le(const void* in) { const u32bit* in_32 = static_cast(in); __vector unsigned int R0 = vec_ld(0, in_32); __vector unsigned int R1 = vec_ld(12, in_32); __vector unsigned char perm = vec_lvsl(0, in_32); perm = vec_xor(perm, vec_splat_u8(3)); R0 = vec_perm(R0, R1, perm); return SIMD_Altivec(R0); } static SIMD_Altivec load_be(const void* in) { const u32bit* in_32 = static_cast(in); __vector unsigned int R0 = vec_ld(0, in_32); __vector unsigned int R1 = vec_ld(12, in_32); __vector unsigned char perm = vec_lvsl(0, in_32); R0 = vec_perm(R0, R1, perm); return SIMD_Altivec(R0); } void store_le(byte out[]) const { __vector unsigned char perm = vec_lvsl(0, (u32bit*)0); perm = vec_xor(perm, vec_splat_u8(3)); union { __vector unsigned int V; u32bit R[4]; } vec; vec.V = vec_perm(reg, reg, perm); Botan::store_be(out, vec.R[0], vec.R[1], vec.R[2], vec.R[3]); } void store_be(byte out[]) const { union { __vector unsigned int V; u32bit R[4]; } vec; vec.V = reg; Botan::store_be(out, vec.R[0], vec.R[1], vec.R[2], vec.R[3]); } void rotate_left(size_t rot) { __vector unsigned int rot_vec = (__vector unsigned int){rot, rot, rot, rot}; reg = vec_rl(reg, rot_vec); } void rotate_right(size_t rot) { rotate_left(32 - rot); } void operator+=(const SIMD_Altivec& other) { reg = vec_add(reg, other.reg); } SIMD_Altivec operator+(const SIMD_Altivec& other) const { return vec_add(reg, other.reg); } void operator-=(const SIMD_Altivec& other) { reg = vec_sub(reg, other.reg); } SIMD_Altivec operator-(const SIMD_Altivec& other) const { return vec_sub(reg, other.reg); } void operator^=(const SIMD_Altivec& other) { reg = vec_xor(reg, other.reg); } SIMD_Altivec operator^(const SIMD_Altivec& other) const { return vec_xor(reg, other.reg); } void operator|=(const SIMD_Altivec& other) { reg = vec_or(reg, other.reg); } SIMD_Altivec operator&(const SIMD_Altivec& other) { return vec_and(reg, other.reg); } void operator&=(const SIMD_Altivec& other) { reg = vec_and(reg, other.reg); } SIMD_Altivec operator<<(size_t shift) const { __vector unsigned int shift_vec = (__vector unsigned int){shift, shift, shift, shift}; return vec_sl(reg, shift_vec); } SIMD_Altivec operator>>(size_t shift) const { __vector unsigned int shift_vec = (__vector unsigned int){shift, shift, shift, shift}; return vec_sr(reg, shift_vec); } SIMD_Altivec operator~() const { return vec_nor(reg, reg); } SIMD_Altivec andc(const SIMD_Altivec& other) { // AltiVec does arg1 & ~arg2 rather than SSE's ~arg1 & arg2 return vec_andc(other.reg, reg); } SIMD_Altivec bswap() const { __vector unsigned char perm = vec_lvsl(0, (u32bit*)0); perm = vec_xor(perm, vec_splat_u8(3)); return SIMD_Altivec(vec_perm(reg, reg, perm)); } static void transpose(SIMD_Altivec& B0, SIMD_Altivec& B1, SIMD_Altivec& B2, SIMD_Altivec& B3) { __vector unsigned int T0 = vec_mergeh(B0.reg, B2.reg); __vector unsigned int T1 = vec_mergel(B0.reg, B2.reg); __vector unsigned int T2 = vec_mergeh(B1.reg, B3.reg); __vector unsigned int T3 = vec_mergel(B1.reg, B3.reg); B0.reg = vec_mergeh(T0, T2); B1.reg = vec_mergel(T0, T2); B2.reg = vec_mergeh(T1, T3); B3.reg = vec_mergel(T1, T3); } private: SIMD_Altivec(__vector unsigned int input) { reg = input; } __vector unsigned int reg; }; } #endif #endif