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/*
* Runtime CPU detection
* (C) 2009-2010,2013 Jack Lloyd
*
* Botan is released under the Simplified BSD License (see license.txt)
*/
#ifndef BOTAN_CPUID_H__
#define BOTAN_CPUID_H__
#include <botan/types.h>
#include <iosfwd>
namespace Botan {
/**
* A class handling runtime CPU feature detection
*
* Currently this class supports only x86 (via CPUID) and PowerPC (AltiVec detection)
*/
class BOTAN_DLL CPUID
{
public:
/**
* Probe the CPU and see what extensions are supported
*/
static void initialize();
static bool has_simd_32();
static void print(std::ostream& o);
/**
* Return a best guess of the cache line size
*/
static size_t cache_line_size()
{
if(!g_initialized)
{
initialize();
}
return g_cache_line_size;
}
enum CPUID_bits {
#if defined(BOTAN_TARGET_CPU_IS_X86_FAMILY)
// This matches the layout of cpuid(1)
CPUID_RDTSC_BIT = 4,
CPUID_SSE2_BIT = 26,
CPUID_CLMUL_BIT = 33,
CPUID_SSSE3_BIT = 41,
CPUID_SSE41_BIT = 51,
CPUID_SSE42_BIT = 52,
CPUID_AESNI_BIT = 57,
CPUID_RDRAND_BIT = 62,
CPUID_AVX2_BIT = 64+5,
CPUID_BMI2_BIT = 64+8,
CPUID_AVX512F_BIT = 64+16,
CPUID_RDSEED_BIT = 64+18,
CPUID_ADX_BIT = 64+19,
CPUID_SHA_BIT = 64+29,
#endif
#if defined(BOTAN_TARGET_CPU_IS_PPC_FAMILY)
CPUID_ALTIVEC_BIT = 0
#endif
// TODO: ARMv8 feature detection
};
#if defined(BOTAN_TARGET_CPU_IS_PPC_FAMILY)
/**
* Check if the processor supports AltiVec/VMX
*/
static bool has_altivec()
{ return has_cpuid_bit(CPUID_ALTIVEC_BIT); }
#endif
#if defined(BOTAN_TARGET_CPU_IS_X86_FAMILY)
/**
* Check if the processor supports RDTSC
*/
static bool has_rdtsc()
{ return has_cpuid_bit(CPUID_RDTSC_BIT); }
/**
* Check if the processor supports SSE2
*/
static bool has_sse2()
{ return has_cpuid_bit(CPUID_SSE2_BIT); }
/**
* Check if the processor supports SSSE3
*/
static bool has_ssse3()
{ return has_cpuid_bit(CPUID_SSSE3_BIT); }
/**
* Check if the processor supports SSE4.1
*/
static bool has_sse41()
{ return has_cpuid_bit(CPUID_SSE41_BIT); }
/**
* Check if the processor supports SSE4.2
*/
static bool has_sse42()
{ return has_cpuid_bit(CPUID_SSE42_BIT); }
/**
* Check if the processor supports AVX2
*/
static bool has_avx2()
{ return has_cpuid_bit(CPUID_AVX2_BIT); }
/**
* Check if the processor supports AVX-512F
*/
static bool has_avx512f()
{ return has_cpuid_bit(CPUID_AVX512F_BIT); }
/**
* Check if the processor supports BMI2
*/
static bool has_bmi2()
{ return has_cpuid_bit(CPUID_BMI2_BIT); }
/**
* Check if the processor supports AES-NI
*/
static bool has_aes_ni()
{ return has_cpuid_bit(CPUID_AESNI_BIT); }
/**
* Check if the processor supports CLMUL
*/
static bool has_clmul()
{ return has_cpuid_bit(CPUID_CLMUL_BIT); }
/**
* Check if the processor supports Intel SHA extension
*/
static bool has_intel_sha()
{ return has_cpuid_bit(CPUID_SHA_BIT); }
/**
* Check if the processor supports ADX extension
*/
static bool has_adx()
{ return has_cpuid_bit(CPUID_ADX_BIT); }
/**
* Check if the processor supports RDRAND
*/
static bool has_rdrand()
{ return has_cpuid_bit(CPUID_RDRAND_BIT); }
/**
* Check if the processor supports RDSEED
*/
static bool has_rdseed()
{ return has_cpuid_bit(CPUID_RDSEED_BIT); }
#endif
/*
* Clear a CPUID bit
* Call CPUID::initialize to reset
*/
static void clear_cpuid_bit(CPUID_bits bit)
{
BOTAN_ASSERT(bit < 128, "CPUID bit within bounds");
const uint64_t mask = ~(static_cast<uint64_t>(1) << (bit % 64));
g_processor_flags[bit/64] &= mask;
}
static bool has_cpuid_bit(CPUID_bits elem)
{
if(!g_initialized)
initialize();
const size_t bit = static_cast<size_t>(elem);
BOTAN_ASSERT(bit < 128, "CPUID bit within bounds");
return ((g_processor_flags[bit/64] >> (bit % 64)) & 1);
}
private:
static bool g_initialized;
static size_t g_cache_line_size;
static u64bit g_processor_flags[2];
};
}
#endif
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