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More rand implementations

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This commit is contained in:
Dmitrii Kovalkov 2020-05-20 14:42:21 +02:00
parent 66d530e901
commit 90bc3e6136
4 changed files with 272 additions and 174 deletions
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317
src/Functions/FunctionsRandom.cpp
View File

@ -3,19 +3,18 @@
#include <Common/HashTable/Hash.h>
#include <Common/randomSeed.h>
#include <common/unaligned.h>
#include <x86intrin.h>
namespace DB
{
/*
// TODO(dakovalkov): remove this workaround.
#pragma GCC diagnostic ignored "-Wvector-operation-performance"
#if !defined(__clang__)
# pragma GCC diagnostic ignored "-Wvector-operation-performance"
#endif
DECLARE_MULTITARGET_CODE(
*/
namespace
{
/// NOTE Probably
@ -45,10 +44,16 @@ namespace
}
};
void seed(LinearCongruentialGenerator & generator, intptr_t additional_seed)
UInt64 calcSeed(UInt64 rand_seed, UInt64 additional_seed)
{
generator.seed(intHash64(randomSeed() ^ intHash64(additional_seed)));
return intHash64(rand_seed ^ intHash64(additional_seed));
}
void seed(LinearCongruentialGenerator & generator, UInt64 rand_seed, intptr_t additional_seed)
{
generator.seed(calcSeed(rand_seed, additional_seed));
}
}
void RandImpl::execute(char * output, size_t size)
@ -58,10 +63,12 @@ void RandImpl::execute(char * output, size_t size)
LinearCongruentialGenerator generator2;
LinearCongruentialGenerator generator3;
seed(generator0, 0xfb4121280b2ab902ULL + reinterpret_cast<intptr_t>(output));
seed(generator1, 0x0121cf76df39c673ULL + reinterpret_cast<intptr_t>(output));
seed(generator2, 0x17ae86e3a19a602fULL + reinterpret_cast<intptr_t>(output));
seed(generator3, 0x8b6e16da7e06d622ULL + reinterpret_cast<intptr_t>(output));
UInt64 rand_seed = randomSeed();
seed(generator0, rand_seed, 0xfb4121280b2ab902ULL + reinterpret_cast<intptr_t>(output));
seed(generator1, rand_seed, 0x0121cf76df39c673ULL + reinterpret_cast<intptr_t>(output));
seed(generator2, rand_seed, 0x17ae86e3a19a602fULL + reinterpret_cast<intptr_t>(output));
seed(generator3, rand_seed, 0x8b6e16da7e06d622ULL + reinterpret_cast<intptr_t>(output));
for (const char * end = output + size; output < end; output += 16)
{
@ -73,55 +80,6 @@ void RandImpl::execute(char * output, size_t size)
/// It is guaranteed (by PaddedPODArray) that we can overwrite up to 15 bytes after end.
}
void RandImpl2::execute(char * output, size_t size)
{
if (size == 0)
return;
LinearCongruentialGenerator generator0;
LinearCongruentialGenerator generator1;
LinearCongruentialGenerator generator2;
LinearCongruentialGenerator generator3;
LinearCongruentialGenerator generator4;
LinearCongruentialGenerator generator5;
LinearCongruentialGenerator generator6;
LinearCongruentialGenerator generator7;
seed(generator0, 0xfaaae481acb5874aULL + reinterpret_cast<intptr_t>(output));
seed(generator1, 0x3181a34f32887db6ULL + reinterpret_cast<intptr_t>(output));
seed(generator2, 0xb6970e4a91b66afdULL + reinterpret_cast<intptr_t>(output));
seed(generator3, 0xc16062649e83dc13ULL + reinterpret_cast<intptr_t>(output));
seed(generator4, 0xbb093972da5c8d92ULL + reinterpret_cast<intptr_t>(output));
seed(generator5, 0xc37dcc410dcfed31ULL + reinterpret_cast<intptr_t>(output));
seed(generator6, 0x45e1526b7a4367d5ULL + reinterpret_cast<intptr_t>(output));
seed(generator7, 0x99c2759203868a7fULL + reinterpret_cast<intptr_t>(output));
const char * end = output + size;
for (; (end - output + 15) <= 32; output += 32)
{
unalignedStore<UInt32>(output, generator0.next());
unalignedStore<UInt32>(output + 4, generator1.next());
unalignedStore<UInt32>(output + 8, generator2.next());
unalignedStore<UInt32>(output + 12, generator3.next());
unalignedStore<UInt32>(output + 16, generator4.next());
unalignedStore<UInt32>(output + 20, generator5.next());
unalignedStore<UInt32>(output + 24, generator6.next());
unalignedStore<UInt32>(output + 28, generator7.next());
}
if (end - output > 0)
{
unalignedStore<UInt32>(output, generator0.next());
unalignedStore<UInt32>(output + 4, generator1.next());
unalignedStore<UInt32>(output + 8, generator2.next());
unalignedStore<UInt32>(output + 12, generator3.next());
output += 16;
}
}
/*
typedef UInt64 UInt64x16 __attribute__ ((vector_size (128)));
typedef UInt64 UInt64x8 __attribute__ ((vector_size (64)));
typedef UInt64 UInt64x4 __attribute__ ((vector_size (32)));
@ -130,58 +88,85 @@ typedef UInt32 UInt32x16 __attribute__ ((vector_size (64)));
typedef UInt32 UInt32x8 __attribute__ ((vector_size (32)));
typedef UInt32 UInt32x4 __attribute__ ((vector_size (16)));
void RandImpl3::execute(char * output, size_t size)
template <int Size>
struct DummyStruct;
template <>
struct DummyStruct<4>
{
using UInt64Type = UInt64x4;
using UInt32Type = UInt32x4;
};
template <>
struct DummyStruct<8>
{
using UInt64Type = UInt64x8;
using UInt32Type = UInt32x8;
};
template <>
struct DummyStruct<16>
{
using UInt64Type = UInt64x16;
using UInt32Type = UInt32x16;
};
template <int Size>
using VecUInt64 = typename DummyStruct<Size>::UInt64Type;
template <int Size>
using VecUInt32 = typename DummyStruct<Size>::UInt32Type;
namespace {
constexpr std::array<UInt64, 16> random_numbers = {
0x0c8ff307dabc0c4cULL,
0xf4bce78bf3821c1bULL,
0x4eb628a1e189c21aULL,
0x85ae000d253e0dbcULL,
0xc98073e6480f8a10ULL,
0xb17e9b70a084d570ULL,
0x1361c752b768da8cULL,
0x3d915f60c06d144dULL,
0xd5bc9b7aced79587ULL,
0x66c28000ba8a66cfULL,
0x0fb58da7a48820f5ULL,
0x540ee1b57aa861a1ULL,
0x212f11936ef2db04ULL,
0xa3939cd900edcc58ULL,
0xc676c84420170102ULL,
0xcbdc824e8b4bf3edULL,
};
};
template <int VectorSize>
void RandVecImpl<VectorSize>::execute(char * output, size_t size)
{
static_assert(VectorSize >= 4);
static_assert(VectorSize <= random_numbers.size());
if (size == 0)
return;
char * end = output + size;
UInt64x4 generators = {
0xfb4121280b2ab902ULL + reinterpret_cast<intptr_t>(output),
0x0121cf76df39c673ULL + reinterpret_cast<intptr_t>(output),
0x17ae86e3a19a602fULL + reinterpret_cast<intptr_t>(output),
0x8b6e16da7e06d622ULL + reinterpret_cast<intptr_t>(output),
};
constexpr int bytes_per_write = sizeof(UInt32x4);
constexpr int safe_overwrite = 15;
constexpr int bytes_per_write = sizeof(VecUInt32<VectorSize>);
UInt64 rand_seed = randomSeed();
VecUInt64<VectorSize> generators{};
for (int i = 0; i < VectorSize; ++i)
generators[i] = calcSeed(rand_seed, random_numbers[VectorSize] + reinterpret_cast<intptr_t>(output));
while ((end - output) + safe_overwrite >= bytes_per_write)
{
generators *= LinearCongruentialGenerator::a;
generators += LinearCongruentialGenerator::c;
unalignedStore<UInt32x4>(output, __builtin_convertvector(generators, UInt32x4));
output += bytes_per_write;
}
}
void RandImpl4::execute(char * output, size_t size)
{
if (size == 0)
return;
char * end = output + size;
UInt64x8 generators = {
0x5f186ce5faee450bULL + reinterpret_cast<intptr_t>(output),
0x9adb2ca3c72ac2eeULL + reinterpret_cast<intptr_t>(output),
0x07acf8bfa2537705ULL + reinterpret_cast<intptr_t>(output),
0x692b1b533834db92ULL + reinterpret_cast<intptr_t>(output),
0x5148b84cdda30081ULL + reinterpret_cast<intptr_t>(output),
0xe17b8a75a301ad47ULL + reinterpret_cast<intptr_t>(output),
0x6d4a5d69ed2a5f56ULL + reinterpret_cast<intptr_t>(output),
0x114e23266201b333ULL + reinterpret_cast<intptr_t>(output),
};
constexpr int bytes_per_write = sizeof(UInt32x8);
constexpr int safe_overwrite = 15;
while ((end - output) + safe_overwrite >= bytes_per_write)
{
generators *= LinearCongruentialGenerator::a;
generators += LinearCongruentialGenerator::c;
unalignedStore<UInt32x8>(output, __builtin_convertvector(generators, UInt32x8));
VecUInt32<VectorSize> values = __builtin_convertvector(generators >> 16, VecUInt32<VectorSize>);
unalignedStore<VecUInt32<VectorSize>>(output, values);
output += bytes_per_write;
}
@ -189,7 +174,7 @@ void RandImpl4::execute(char * output, size_t size)
{
generators *= LinearCongruentialGenerator::a;
generators += LinearCongruentialGenerator::c;
UInt32x8 values = __builtin_convertvector(generators, UInt32x8);
VecUInt32<VectorSize> values = __builtin_convertvector(generators >> 16, VecUInt32<VectorSize>);
for (int i = 0; (end - output) > 0; ++i)
{
unalignedStore<UInt32>(output, values[i]);
@ -198,49 +183,50 @@ void RandImpl4::execute(char * output, size_t size)
}
}
void RandImpl5::execute(char * output, size_t size)
template struct RandVecImpl<4>;
template struct RandVecImpl<8>;
template struct RandVecImpl<16>;
template <int VectorSize>
void RandVecImpl2<VectorSize>::execute(char * output, size_t size)
{
static_assert(VectorSize >= 4);
if (size == 0)
return;
char * end = output + size;
UInt64x16 generators = {
0xfb4121280b2ab902ULL + reinterpret_cast<intptr_t>(output),
0x0121cf76df39c673ULL + reinterpret_cast<intptr_t>(output),
0x17ae86e3a19a602fULL + reinterpret_cast<intptr_t>(output),
0x8b6e16da7e06d622ULL + reinterpret_cast<intptr_t>(output),
0xfb4121f80b2ab902ULL + reinterpret_cast<intptr_t>(output),
0x0122cf767f39c633ULL + reinterpret_cast<intptr_t>(output),
0x14ae86e3a79a502fULL + reinterpret_cast<intptr_t>(output),
0x876316da7e06d622ULL + reinterpret_cast<intptr_t>(output),
0xfb4821280b2ab912ULL + reinterpret_cast<intptr_t>(output),
0x0126cf76df39c633ULL + reinterpret_cast<intptr_t>(output),
0x17a486e3a19a602fULL + reinterpret_cast<intptr_t>(output),
0x8b6216da7e08d622ULL + reinterpret_cast<intptr_t>(output),
0xfb4101f80b5ab902ULL + reinterpret_cast<intptr_t>(output),
0x01226f767f34c633ULL + reinterpret_cast<intptr_t>(output),
0x14ae86e3a75a502fULL + reinterpret_cast<intptr_t>(output),
0x876e36da7e36d622ULL + reinterpret_cast<intptr_t>(output),
};
constexpr int bytes_per_write = sizeof(UInt32x16);
constexpr int safe_overwrite = 15;
constexpr int bytes_per_write = 2 * sizeof(VecUInt32<VectorSize>);
UInt64 rand_seed = randomSeed();
VecUInt64<VectorSize> gens1{}, gens2{};
for (int i = 0; i < VectorSize; ++i)
{
gens1[i] = calcSeed(rand_seed, i * 1123465ull * reinterpret_cast<intptr_t>(output));
gens2[i] = calcSeed(rand_seed, i * 6432453ull * reinterpret_cast<intptr_t>(output));
}
while ((end - output) + safe_overwrite >= bytes_per_write)
{
generators *= LinearCongruentialGenerator::a;
generators += LinearCongruentialGenerator::c;
unalignedStore<UInt32x16>(output, __builtin_convertvector(generators, UInt32x16));
gens1 *= LinearCongruentialGenerator::a;
gens1 += LinearCongruentialGenerator::c;
VecUInt32<VectorSize> values1 = __builtin_convertvector(gens1 >> 16, VecUInt32<VectorSize>);
unalignedStore<VecUInt32<VectorSize>>(output, values1);
gens2 *= LinearCongruentialGenerator::a;
gens2 += LinearCongruentialGenerator::c;
VecUInt32<VectorSize> values2 = __builtin_convertvector(gens2 >> 16, VecUInt32<VectorSize>);
unalignedStore<VecUInt32<VectorSize>>(output, values2);
output += bytes_per_write;
}
if ((end - output) > 0)
while ((end - output) > 0)
{
generators *= LinearCongruentialGenerator::a;
generators += LinearCongruentialGenerator::c;
UInt32x16 values = __builtin_convertvector(generators, UInt32x16);
for (int i = 0; (end - output) > 0; ++i)
gens1 *= LinearCongruentialGenerator::a;
gens1 += LinearCongruentialGenerator::c;
VecUInt32<VectorSize> values = __builtin_convertvector(gens1 >> 16, VecUInt32<VectorSize>);
for (int i = 0; (end - output) > 0 && i < VectorSize; ++i)
{
unalignedStore<UInt32>(output, values[i]);
output += sizeof(UInt32);
@ -248,8 +234,73 @@ void RandImpl5::execute(char * output, size_t size)
}
}
template struct RandVecImpl2<4>;
template struct RandVecImpl2<8>;
template struct RandVecImpl2<16>;
// template <int VectorSize>
// void RandVecImpl4<VectorSize>::execute(char * output, size_t size)
// {
// static_assert(VectorSize >= 4);
// if (size == 0)
// return;
// char * end = output + size;
// constexpr int safe_overwrite = 15;
// constexpr int bytes_per_write = 4 * sizeof(VecUInt32<VectorSize>);
// VecUInt64<VectorSize> gens1{}, gens2{}, gens3{}, gens4{};
// for (int i = 0; i < VectorSize; ++i)
// {
// gens1[i] = calcSeed(i * 1123465ull * reinterpret_cast<intptr_t>(output));
// gens2[i] = calcSeed(i * 6432453ull * reinterpret_cast<intptr_t>(output));
// gens3[i] = calcSeed(i * 1346434ull * reinterpret_cast<intptr_t>(output));
// gens4[i] = calcSeed(i * 5344753ull * reinterpret_cast<intptr_t>(output));
// }
// while ((end - output) + safe_overwrite >= bytes_per_write)
// {
// gens1 *= LinearCongruentialGenerator::a;
// gens1 += LinearCongruentialGenerator::c;
// VecUInt32<VectorSize> values1 = __builtin_convertvector(gens1 >> 16, VecUInt32<VectorSize>);
// unalignedStore<VecUInt32<VectorSize>>(output, values1);
// gens2 *= LinearCongruentialGenerator::a;
// gens2 += LinearCongruentialGenerator::c;
// VecUInt32<VectorSize> values2 = __builtin_convertvector(gens2 >> 16, VecUInt32<VectorSize>);
// unalignedStore<VecUInt32<VectorSize>>(output, values2);
// gens3 *= LinearCongruentialGenerator::a;
// gens3 += LinearCongruentialGenerator::c;
// VecUInt32<VectorSize> values3 = __builtin_convertvector(gens3 >> 16, VecUInt32<VectorSize>);
// unalignedStore<VecUInt32<VectorSize>>(output, values3);
// gens4 *= LinearCongruentialGenerator::a;
// gens4 += LinearCongruentialGenerator::c;
// VecUInt32<VectorSize> values4 = __builtin_convertvector(gens4 >> 16, VecUInt32<VectorSize>);
// unalignedStore<VecUInt32<VectorSize>>(output, values4);
// output += bytes_per_write;
// }
// while ((end - output) > 0)
// {
// gens1 *= LinearCongruentialGenerator::a;
// gens1 += LinearCongruentialGenerator::c;
// VecUInt32<VectorSize> values = __builtin_convertvector(gens1 >> 16, VecUInt32<VectorSize>);
// for (int i = 0; (end - output) > 0 && i < VectorSize; i += 4)
// {
// unalignedStore<UInt32>(output, values[i]);
// unalignedStore<UInt32>(output + 4, values[i + 1]);
// unalignedStore<UInt32>(output + 8, values[i + 2]);
// unalignedStore<UInt32>(output + 12, values[i + 3]);
// output += 16;
// }
// }
// }
// template struct RandVecImpl2<4>;
// template struct RandVecImpl2<8>;
// template struct RandVecImpl2<16>;
) //DECLARE_MULTITARGET_CODE
*/
}

125
src/Functions/FunctionsRandom.h
View File

@ -36,26 +36,20 @@ namespace ErrorCodes
* This means that the timer must be of sufficient resolution to give different values to each block.
*/
/*
DECLARE_MULTITARGET_CODE(
*/
struct RandImpl
{
static void execute(char * output, size_t size);
static String getImplementationTag() { return ToString(TargetArch::Default); }
static String getImplementationTag() { return ToString(BuildArch); }
};
struct RandImpl2
{
static void execute(char * output, size_t size);
static String getImplementationTag() { return ToString(TargetArch::Default) + "_v2"; }
static String getImplementationTag() { return ToString(BuildArch) + "_v2"; }
};
/*
struct RandImpl3
{
static void execute(char * output, size_t size);
@ -74,9 +68,27 @@ struct RandImpl5
static String getImplementationTag() { return ToString(BuildArch) + "_v5"; }
};
) // DECLARE_MULTITARGET_CODE
template <int VectorSize>
struct RandVecImpl
{
static void execute(char * outpu, size_t size);
static String getImplementationTag() { return ToString(BuildArch) + "_vec_" + toString(VectorSize); }
};
*/
template <int VectorSize>
struct RandVecImpl2
{
static void execute(char * outpu, size_t size);
static String getImplementationTag() { return ToString(BuildArch) + "_vec2_" + toString(VectorSize); }
};
struct RandImpl6
{
static void execute(char * outpu, size_t size);
static String getImplementationTag() { return ToString(BuildArch) + "_v6"; }
};
) // DECLARE_MULTITARGET_CODE
template <typename RandImpl, typename ToType, typename Name>
class FunctionRandomImpl : public IFunction
@ -125,45 +137,80 @@ public:
};
template <typename ToType, typename Name>
class FunctionRandom : public FunctionRandomImpl<RandImpl2, ToType, Name>
class FunctionRandom : public FunctionRandomImpl<TargetSpecific::Default::RandImpl, ToType, Name>
{
public:
FunctionRandom(const Context & context) : selector(context)
{
// selector.registerImplementation<TargetArch::Default,
// FunctionRandomImpl<TargetSpecific::Default::RandImpl, ToType, Name>>();
selector.registerImplementation<TargetArch::Default,
FunctionRandomImpl<RandImpl2, ToType, Name>>();
FunctionRandomImpl<TargetSpecific::Default::RandImpl, ToType, Name>>();
selector.registerImplementation<TargetArch::Default,
FunctionRandomImpl<TargetSpecific::Default::RandImpl2, ToType, Name>>();
// if constexpr (UseMultitargetCode)
// {
// selector.registerImplementation<TargetArch::SSE42,
// FunctionRandomImpl<TargetSpecific::SSE42::RandImpl, ToType, Name>>();
// selector.registerImplementation<TargetArch::AVX,
// FunctionRandomImpl<TargetSpecific::AVX::RandImpl, ToType, Name>>();
// selector.registerImplementation<TargetArch::AVX2,
// FunctionRandomImpl<TargetSpecific::AVX2::RandImpl, ToType, Name>>();
// selector.registerImplementation<TargetArch::AVX512F,
// FunctionRandomImpl<TargetSpecific::AVX512F::RandImpl, ToType, Name>>();
if constexpr (UseMultitargetCode)
{
selector.registerImplementation<TargetArch::SSE42,
FunctionRandomImpl<TargetSpecific::SSE42::RandImpl, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX,
FunctionRandomImpl<TargetSpecific::AVX::RandImpl, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX2,
FunctionRandomImpl<TargetSpecific::AVX2::RandImpl, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX512F,
FunctionRandomImpl<TargetSpecific::AVX512F::RandImpl, ToType, Name>>();
// selector.registerImplementation<TargetArch::AVX2,
// FunctionRandomImpl<TargetSpecific::AVX2::RandImpl2, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX2,
FunctionRandomImpl<TargetSpecific::AVX2::RandImpl2, ToType, Name>>();
// selector.registerImplementation<TargetArch::Default,
// FunctionRandomImpl<TargetSpecific::Default::RandImpl3, ToType, Name>>();
// selector.registerImplementation<TargetArch::AVX2,
// FunctionRandomImpl<TargetSpecific::AVX2::RandImpl3, ToType, Name>>();
selector.registerImplementation<TargetArch::Default,
FunctionRandomImpl<TargetSpecific::Default::RandImpl3, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX2,
FunctionRandomImpl<TargetSpecific::AVX2::RandImpl3, ToType, Name>>();
// selector.registerImplementation<TargetArch::Default,
// FunctionRandomImpl<TargetSpecific::Default::RandImpl4, ToType, Name>>();
// selector.registerImplementation<TargetArch::AVX2,
// FunctionRandomImpl<TargetSpecific::AVX2::RandImpl4, ToType, Name>>();
selector.registerImplementation<TargetArch::Default,
FunctionRandomImpl<TargetSpecific::Default::RandImpl4, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX2,
FunctionRandomImpl<TargetSpecific::AVX2::RandImpl4, ToType, Name>>();
// selector.registerImplementation<TargetArch::Default,
// FunctionRandomImpl<TargetSpecific::Default::RandImpl5, ToType, Name>>();
// selector.registerImplementation<TargetArch::AVX2,
// FunctionRandomImpl<TargetSpecific::AVX2::RandImpl5, ToType, Name>>();
// }
selector.registerImplementation<TargetArch::Default,
FunctionRandomImpl<TargetSpecific::Default::RandImpl5, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX2,
FunctionRandomImpl<TargetSpecific::AVX2::RandImpl5, ToType, Name>>();
// vec impl
selector.registerImplementation<TargetArch::Default,
FunctionRandomImpl<TargetSpecific::Default::RandVecImpl<4>, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX2,
FunctionRandomImpl<TargetSpecific::AVX2::RandVecImpl<4>, ToType, Name>>();
selector.registerImplementation<TargetArch::Default,
FunctionRandomImpl<TargetSpecific::Default::RandVecImpl<8>, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX2,
FunctionRandomImpl<TargetSpecific::AVX2::RandVecImpl<8>, ToType, Name>>();
selector.registerImplementation<TargetArch::Default,
FunctionRandomImpl<TargetSpecific::Default::RandVecImpl<16>, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX2,
FunctionRandomImpl<TargetSpecific::AVX2::RandVecImpl<16>, ToType, Name>>();
// vec impl 2
selector.registerImplementation<TargetArch::Default,
FunctionRandomImpl<TargetSpecific::Default::RandVecImpl2<4>, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX2,
FunctionRandomImpl<TargetSpecific::AVX2::RandVecImpl2<4>, ToType, Name>>();
selector.registerImplementation<TargetArch::Default,
FunctionRandomImpl<TargetSpecific::Default::RandVecImpl2<8>, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX2,
FunctionRandomImpl<TargetSpecific::AVX2::RandVecImpl2<8>, ToType, Name>>();
selector.registerImplementation<TargetArch::Default,
FunctionRandomImpl<TargetSpecific::Default::RandVecImpl2<16>, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX2,
FunctionRandomImpl<TargetSpecific::AVX2::RandVecImpl2<16>, ToType, Name>>();
selector.registerImplementation<TargetArch::AVX2,
FunctionRandomImpl<TargetSpecific::AVX2::RandImpl6, ToType, Name>>();
}
}
void executeImpl(Block & block, const ColumnNumbers & arguments, size_t result, size_t input_rows_count) override

2
src/Functions/generateUUIDv4.cpp
View File

@ -33,7 +33,7 @@ public:
size_t size = input_rows_count;
vec_to.resize(size);
// TODO(dakovalkov): rewrite this workaround
RandImpl::execute(reinterpret_cast<char *>(vec_to.data()), vec_to.size() * sizeof(UInt128));
TargetSpecific::Default::RandImpl::execute(reinterpret_cast<char *>(vec_to.data()), vec_to.size() * sizeof(UInt128));
for (UInt128 & uuid: vec_to)
{

2
src/Functions/randConstant.cpp
View File

@ -100,7 +100,7 @@ public:
typename ColumnVector<ToType>::Container vec_to(1);
// TODO(dakovalkov): Rewrite this workaround
RandImpl::execute(reinterpret_cast<char *>(vec_to.data()), sizeof(ToType));
TargetSpecific::Default::RandImpl::execute(reinterpret_cast<char *>(vec_to.data()), sizeof(ToType));
ToType value = vec_to[0];
return std::make_unique<FunctionBaseRandomConstant<ToType, Name>>(value, argument_types, return_type);