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#include "vec.h"
namespace {
// NB: avoid using `at::vec::map<>` on bfloat16 or half
// Llama4TextL2Norm
template <typename scalar_t>
void l2norm_kernel_impl(
scalar_t* __restrict__ output,
const scalar_t* __restrict__ input,
int64_t batch_size,
int64_t hidden_size,
float eps = 1e-5) {
using bVec = at::vec::Vectorized<scalar_t>;
using fVec = at::vec::Vectorized<float>;
constexpr int kVecSize = bVec::size();
at::parallel_for(0, batch_size, 0, [&](int64_t begin, int64_t end) {
for (int64_t i = begin; i < end; ++i) {
// local ptrs
scalar_t* __restrict__ out_ptr = output + i * hidden_size;
const scalar_t* __restrict__ input_ptr = input + i * hidden_size;
fVec sum_fvec = fVec(float(0));
float sum_val = float(0);
int64_t d;
#pragma GCC unroll 4
for (d = 0; d <= hidden_size - kVecSize; d += kVecSize) {
bVec x_bvec = bVec::loadu(input_ptr + d);
fVec x_fvec0, x_fvec1;
std::tie(x_fvec0, x_fvec1) = at::vec::convert_to_float(x_bvec);
sum_fvec += x_fvec0 * x_fvec0;
sum_fvec += x_fvec1 * x_fvec1;
}
#pragma GCC unroll 4
for (; d < hidden_size; ++d) {
float x_val = static_cast<float>(input_ptr[d]);
sum_val += x_val * x_val;
}
sum_val += vec_reduce_sum(sum_fvec);
float rsqrt_var = float(1) / std::sqrt(sum_val / hidden_size + eps);
const fVec scale_fvec = fVec(rsqrt_var);
#pragma GCC unroll 4
for (d = 0; d <= hidden_size - kVecSize; d += kVecSize) {
bVec x_bvec = bVec::loadu(input_ptr + d);
fVec x_fvec0, x_fvec1;
std::tie(x_fvec0, x_fvec1) = at::vec::convert_to_float(x_bvec);
x_fvec0 = x_fvec0 * scale_fvec;
x_fvec1 = x_fvec1 * scale_fvec;
bVec out_bvec = convert_from_float_ext<scalar_t>(x_fvec0, x_fvec1);
out_bvec.store(out_ptr + d);
}
#pragma GCC unroll 4
for (; d < hidden_size; ++d) {
float x_val = static_cast<float>(input_ptr[d]);
out_ptr[d] = static_cast<scalar_t>(x_val * rsqrt_var);
}
}
});
}
template <typename scalar_t, typename func_t, typename vec_func_t>
void rmsnorm_kernel_impl(
scalar_t* __restrict__ output,
const scalar_t* __restrict__ input,
const scalar_t* __restrict__ weight,
int64_t batch_size,
int64_t hidden_size,
int64_t input_strideN,
const func_t& f,
const vec_func_t& vf,
float eps = 1e-5) {
using bVec = at::vec::Vectorized<scalar_t>;
using fVec = at::vec::Vectorized<float>;
constexpr int kVecSize = bVec::size();
at::parallel_for(0, batch_size, 0, [&](int64_t begin, int64_t end) {
for (int64_t i = begin; i < end; ++i) {
// local ptrs
scalar_t* __restrict__ out_ptr = output + i * hidden_size;
const scalar_t* __restrict__ input_ptr = input + i * input_strideN;
fVec sum_fvec = fVec(float(0));
float sum_val = float(0);
int64_t d;
#pragma GCC unroll 4
for (d = 0; d <= hidden_size - kVecSize; d += kVecSize) {
bVec x_bvec = bVec::loadu(input_ptr + d);
fVec x_fvec0, x_fvec1;
std::tie(x_fvec0, x_fvec1) = at::vec::convert_to_float(x_bvec);
sum_fvec += x_fvec0 * x_fvec0;
sum_fvec += x_fvec1 * x_fvec1;
}
#pragma GCC unroll 4
for (; d < hidden_size; ++d) {
float x_val = static_cast<float>(input_ptr[d]);
sum_val += x_val * x_val;
}
sum_val += vec_reduce_sum(sum_fvec);
float rsqrt_var = float(1) / std::sqrt(sum_val / hidden_size + eps);
const fVec scale_fvec = fVec(rsqrt_var);
#pragma GCC unroll 4
for (d = 0; d <= hidden_size - kVecSize; d += kVecSize) {
bVec x_bvec = bVec::loadu(input_ptr + d);
fVec x_fvec0, x_fvec1;
std::tie(x_fvec0, x_fvec1) = at::vec::convert_to_float(x_bvec);
bVec w_bvec = bVec::loadu(weight + d);
fVec w_fvec0, w_fvec1;
std::tie(w_fvec0, w_fvec1) = at::vec::convert_to_float(w_bvec);
x_fvec0 = x_fvec0 * scale_fvec * vf(w_fvec0);
x_fvec1 = x_fvec1 * scale_fvec * vf(w_fvec1);
bVec out_bvec = convert_from_float_ext<scalar_t>(x_fvec0, x_fvec1);
out_bvec.store(out_ptr + d);
}
#pragma GCC unroll 4
for (; d < hidden_size; ++d) {
float x_val = static_cast<float>(input_ptr[d]);
float w_val = static_cast<float>(weight[d]);
out_ptr[d] = static_cast<scalar_t>(x_val * rsqrt_var * f(w_val));
}
}
});
}
template <typename scalar_t>
void gemma3_rmsnorm_kernel_4d_impl(
scalar_t* __restrict__ output,
const scalar_t* __restrict__ input,
const scalar_t* __restrict__ weight,
int64_t batch_size,
int64_t num_head,
int64_t seq_len,
int64_t hidden_size,
int64_t input_strideB,
int64_t input_strideH,
int64_t input_strideS,
int64_t output_strideB,
int64_t output_strideH,
int64_t output_strideS,
float eps = 1e-5) {
using bVec = at::vec::Vectorized<scalar_t>;
using fVec = at::vec::Vectorized<float>;
constexpr int kVecSize = bVec::size();
at::parallel_for(0, batch_size * num_head * seq_len, 0, [&](int64_t begin, int64_t end) {
int64_t bi{0}, hi{0}, si{0};
data_index_init(begin, bi, batch_size, hi, num_head, si, seq_len);
for (int64_t i = begin; i < end; ++i) {
// local ptrs
scalar_t* __restrict__ out_ptr = output + bi * output_strideB + hi * output_strideH + si * output_strideS;
const scalar_t* __restrict__ input_ptr = input + bi * input_strideB + hi * input_strideH + si * input_strideS;
fVec sum_fvec = fVec(float(0));
float sum_val = float(0);
fVec one_fvec = fVec(float(1));
int64_t d;
#pragma GCC unroll 4
for (d = 0; d <= hidden_size - kVecSize; d += kVecSize) {
bVec x_bvec = bVec::loadu(input_ptr + d);
fVec x_fvec0, x_fvec1;
std::tie(x_fvec0, x_fvec1) = at::vec::convert_to_float(x_bvec);
sum_fvec += x_fvec0 * x_fvec0;
sum_fvec += x_fvec1 * x_fvec1;
}
#pragma GCC unroll 4
for (; d < hidden_size; ++d) {
float x_val = static_cast<float>(input_ptr[d]);
sum_val += x_val * x_val;
}
sum_val += vec_reduce_sum(sum_fvec);
float rsqrt_var = float(1) / std::sqrt(sum_val / hidden_size + eps);
const fVec scale_fvec = fVec(rsqrt_var);
#pragma GCC unroll 4
for (d = 0; d <= hidden_size - kVecSize; d += kVecSize) {
bVec x_bvec = bVec::loadu(input_ptr + d);
fVec x_fvec0, x_fvec1;
std::tie(x_fvec0, x_fvec1) = at::vec::convert_to_float(x_bvec);
bVec w_bvec = bVec::loadu(weight + d);
fVec w_fvec0, w_fvec1;
std::tie(w_fvec0, w_fvec1) = at::vec::convert_to_float(w_bvec);
x_fvec0 = x_fvec0 * scale_fvec * (w_fvec0 + one_fvec);
x_fvec1 = x_fvec1 * scale_fvec * (w_fvec1 + one_fvec);
bVec out_bvec = convert_from_float_ext<scalar_t>(x_fvec0, x_fvec1);
out_bvec.store(out_ptr + d);
}
#pragma GCC unroll 4
for (; d < hidden_size; ++d) {
float x_val = static_cast<float>(input_ptr[d]);
float w_val = static_cast<float>(weight[d]);
out_ptr[d] = static_cast<scalar_t>(x_val * rsqrt_var * (w_val + 1));
}
// move to the next index
data_index_step(bi, batch_size, hi, num_head, si, seq_len);
}
});
}
template <typename scalar_t, typename func_t, typename vec_func_t>
void fused_add_rmsnorm_kernel_impl(
scalar_t* __restrict__ input,
scalar_t* __restrict__ residual,
const scalar_t* __restrict__ weight,
float* __restrict__ buffer,
int64_t batch_size,
int64_t hidden_size,
int64_t input_strideN,
const func_t& f,
const vec_func_t& vf,
float eps = 1e-5) {
using bVec = at::vec::Vectorized<scalar_t>;
using fVec = at::vec::Vectorized<float>;
constexpr int kVecSize = bVec::size();
at::parallel_for(0, batch_size, 0, [&](int64_t begin, int64_t end) {
int tid = at::get_thread_num();
float* __restrict__ buffer_ptr = buffer + tid * hidden_size;
for (int64_t i = begin; i < end; ++i) {
// local ptrs
scalar_t* __restrict__ input_ptr = input + i * input_strideN;
scalar_t* __restrict__ residual_ptr = residual + i * hidden_size;
fVec sum_fvec = fVec(float(0));
float sum_val = float(0);
int64_t d;
#pragma GCC unroll 4
for (d = 0; d <= hidden_size - kVecSize; d += kVecSize) {
bVec x_bvec = bVec::loadu(input_ptr + d);
fVec x_fvec0, x_fvec1;
std::tie(x_fvec0, x_fvec1) = at::vec::convert_to_float(x_bvec);
bVec r_bvec = bVec::loadu(residual_ptr + d);
fVec r_fvec0, r_fvec1;
std::tie(r_fvec0, r_fvec1) = at::vec::convert_to_float(r_bvec);
x_fvec0 += r_fvec0;
x_fvec1 += r_fvec1;
bVec out_bvec = convert_from_float_ext<scalar_t>(x_fvec0, x_fvec1);
out_bvec.store(residual_ptr + d);
sum_fvec += x_fvec0 * x_fvec0;
sum_fvec += x_fvec1 * x_fvec1;
x_fvec0.store(buffer_ptr + d);
x_fvec1.store(buffer_ptr + d + fVec::size());
}
#pragma GCC unroll 4
for (; d < hidden_size; ++d) {
float x_val = static_cast<float>(input_ptr[d]);
float r_val = static_cast<float>(residual_ptr[d]);
x_val += r_val;
residual_ptr[d] = static_cast<scalar_t>(x_val);
sum_val += x_val * x_val;
buffer_ptr[d] = x_val;
}
sum_val += vec_reduce_sum(sum_fvec);
float rsqrt_var = float(1) / std::sqrt(sum_val / hidden_size + eps);
const fVec scale_fvec = fVec(rsqrt_var);
#pragma GCC unroll 4
for (d = 0; d <= hidden_size - kVecSize; d += kVecSize) {
fVec x_fvec0 = fVec::loadu(buffer_ptr + d);
fVec x_fvec1 = fVec::loadu(buffer_ptr + d + fVec::size());
bVec w_bvec = bVec::loadu(weight + d);
fVec w_fvec0, w_fvec1;
std::tie(w_fvec0, w_fvec1) = at::vec::convert_to_float(w_bvec);
x_fvec0 = x_fvec0 * scale_fvec * vf(w_fvec0);
x_fvec1 = x_fvec1 * scale_fvec * vf(w_fvec1);
bVec x_bvec = convert_from_float_ext<scalar_t>(x_fvec0, x_fvec1);
x_bvec.store(input_ptr + d);
}
#pragma GCC unroll 4
for (; d < hidden_size; ++d) {
float x_val = buffer_ptr[d] * rsqrt_var * static_cast<float>(f(weight[d]));
input_ptr[d] = x_val;
}
}
});
}
template <typename scalar_t>
void fused_rmsnorm_gated_kernel_impl(
scalar_t* __restrict__ output,
const scalar_t* __restrict__ input,
const scalar_t* __restrict__ weight,
const scalar_t* __restrict__ gate,
int64_t batch_size,
int64_t hidden_size,
int64_t input_strideN,
float eps = 1e-5) {
using bVec = at::vec::Vectorized<scalar_t>;
using fVec = at::vec::Vectorized<float>;
const fVec one = fVec(1.f);
constexpr int kVecSize = bVec::size();
at::parallel_for(0, batch_size, 0, [&](int64_t begin, int64_t end) {
for (int64_t i = begin; i < end; ++i) {
// local ptrs
scalar_t* __restrict__ out_ptr = output + i * hidden_size;
const scalar_t* __restrict__ input_ptr = input + i * input_strideN;
const scalar_t* __restrict__ gate_ptr = gate + i * hidden_size;
fVec sum_fvec = fVec(float(0));
float sum_val = float(0);
int64_t d;
#pragma GCC unroll 4
for (d = 0; d <= hidden_size - kVecSize; d += kVecSize) {
bVec x_bvec = bVec::loadu(input_ptr + d);
fVec x_fvec0, x_fvec1;
std::tie(x_fvec0, x_fvec1) = at::vec::convert_to_float(x_bvec);
sum_fvec += x_fvec0 * x_fvec0;
sum_fvec += x_fvec1 * x_fvec1;
}
#pragma GCC unroll 4
for (; d < hidden_size; ++d) {
float x_val = static_cast<float>(input_ptr[d]);
sum_val += x_val * x_val;
}
sum_val += vec_reduce_sum(sum_fvec);
float rsqrt_var = float(1) / std::sqrt(sum_val / hidden_size + eps);
const fVec scale_fvec = fVec(rsqrt_var);
#pragma GCC unroll 4
for (d = 0; d <= hidden_size - kVecSize; d += kVecSize) {
bVec x_bvec = bVec::loadu(input_ptr + d);
fVec x_fvec0, x_fvec1;
std::tie(x_fvec0, x_fvec1) = at::vec::convert_to_float(x_bvec);
bVec w_bvec = bVec::loadu(weight + d);
fVec w_fvec0, w_fvec1;
std::tie(w_fvec0, w_fvec1) = at::vec::convert_to_float(w_bvec);
bVec g_bvec = bVec::loadu(gate_ptr + d);
fVec g_fvec0, g_fvec1;
std::tie(g_fvec0, g_fvec1) = at::vec::convert_to_float(g_bvec);
g_fvec0 = g_fvec0 / (one + g_fvec0.neg().exp_u20());
g_fvec1 = g_fvec1 / (one + g_fvec1.neg().exp_u20());
x_fvec0 = x_fvec0 * scale_fvec * w_fvec0 * g_fvec0;
x_fvec1 = x_fvec1 * scale_fvec * w_fvec1 * g_fvec1;
bVec out_bvec = convert_from_float_ext<scalar_t>(x_fvec0, x_fvec1);
out_bvec.store(out_ptr + d);
}
#pragma GCC unroll 4
for (; d < hidden_size; ++d) {
float x_val = static_cast<float>(input_ptr[d]);
float w_val = static_cast<float>(weight[d]);
float g_val = static_cast<float>(gate_ptr[d]);
out_ptr[d] = static_cast<scalar_t>(x_val * rsqrt_var * w_val * g_val / (1.f + std::exp(-g_val)));
}
}
});
}
} // anonymous namespace
template <typename scalar_t>
void fused_add_layernorm_kernel_impl(
scalar_t* __restrict__ input,
scalar_t* __restrict__ residual,
const scalar_t* __restrict__ weight,
float* __restrict__ buffer,
int64_t batch_size,
int64_t hidden_size,
int64_t input_strideN,
float eps = 1e-5) {
using bVec = at::vec::Vectorized<scalar_t>;
using fVec = at::vec::Vectorized<float>;
constexpr int kVecSize = bVec::size();
at::parallel_for(0, batch_size, 0, [&](int64_t begin, int64_t end) {
int tid = at::get_thread_num();
float* __restrict__ buffer_ptr = buffer + tid * hidden_size;
for (int64_t i = begin; i < end; ++i) {
scalar_t* __restrict__ input_ptr = input + i * input_strideN;
scalar_t* __restrict__ residual_ptr{(scalar_t*)nullptr};
if (residual != nullptr) {
residual_ptr = residual + i * hidden_size;
}
// First pass: compute mean and var
fVec sum_fvec{fVec(0.0)}, sum_sq_fvec{fVec(0.0)};
float sum_val{0.0}, sum_sq_val{0.0};
int64_t d{0};
#pragma GCC unroll 4
for (; d <= hidden_size - kVecSize; d += kVecSize) {
bVec x_bvec = bVec::loadu(input_ptr + d);
fVec x_fvec0, x_fvec1;
std::tie(x_fvec0, x_fvec1) = at::vec::convert_to_float(x_bvec);
if (residual_ptr != nullptr) {
bVec r_bvec = bVec::loadu(residual_ptr + d);
fVec r_fvec0, r_fvec1;
std::tie(r_fvec0, r_fvec1) = at::vec::convert_to_float(r_bvec);
x_fvec0 += r_fvec0;
x_fvec1 += r_fvec1;
bVec out_bvec = convert_from_float_ext<scalar_t>(x_fvec0, x_fvec1);
out_bvec.store(residual_ptr + d);
}
sum_fvec += x_fvec0;
sum_fvec += x_fvec1;
sum_sq_fvec += x_fvec0 * x_fvec0;
sum_sq_fvec += x_fvec1 * x_fvec1;
x_fvec0.store(buffer_ptr + d);
x_fvec1.store(buffer_ptr + d + fVec::size());
}
#pragma GCC unroll 4
for (; d < hidden_size; ++d) {
float x_val = static_cast<float>(input_ptr[d]);
if (residual_ptr != nullptr) {
float r_val = static_cast<float>(residual_ptr[d]);
x_val += r_val;
residual_ptr[d] = static_cast<scalar_t>(x_val);
}
sum_val += x_val;
sum_sq_val += x_val * x_val;
buffer_ptr[d] = x_val;
}
// Var(X) = E(X^2) - (E(X))^2
// Refer to FlashInfer impl:
// https://github.com/flashinfer-ai/flashinfer/blob/6bb01d19c2d9ab3b6a3a5e9e97448891a5ed2844/include/flashinfer/norm.cuh#L554
sum_val += vec_reduce_sum(sum_fvec);
sum_sq_val += vec_reduce_sum(sum_sq_fvec);
float mean{sum_val / hidden_size};
float mean_sq{sum_sq_val / hidden_size};
float variance{mean_sq - (mean * mean)};
float rsqrt_var{float(1) / std::sqrt(variance + eps)};
const fVec mean_fvec = fVec(mean);
const fVec scale_fvec = fVec(rsqrt_var);
// Second pass: apply normalization
#pragma GCC unroll 4
for (d = 0; d <= hidden_size - kVecSize; d += kVecSize) {
fVec x_fvec0 = fVec::loadu(buffer_ptr + d);
fVec x_fvec1 = fVec::loadu(buffer_ptr + d + fVec::size());
bVec w_bvec = bVec::loadu(weight + d);
fVec w_fvec0, w_fvec1;
std::tie(w_fvec0, w_fvec1) = at::vec::convert_to_float(w_bvec);
x_fvec0 = (x_fvec0 - mean_fvec) * scale_fvec * w_fvec0;
x_fvec1 = (x_fvec1 - mean_fvec) * scale_fvec * w_fvec1;
bVec x_bvec = convert_from_float_ext<scalar_t>(x_fvec0, x_fvec1);
x_bvec.store(input_ptr + d);
}
#pragma GCC unroll 4
for (; d < hidden_size; ++d) {
float normalized = (buffer_ptr[d] - mean) * rsqrt_var;
float x_val = normalized * static_cast<float>(weight[d]);
input_ptr[d] = static_cast<scalar_t>(x_val);
}
}
});
} // anonymous namespace
// input : {batch_size, hidden_size}
at::Tensor l2norm_cpu(at::Tensor& input, double eps) {
RECORD_FUNCTION("sgl-kernel::l2norm_cpu", std::vector<c10::IValue>({input}));
CHECK_INPUT(input);
CHECK_DIM(2, input);
int64_t batch_size = input.size(0);
int64_t hidden_size = input.size(1);
at::Tensor output = at::empty_like(input);
AT_DISPATCH_REDUCED_FLOATING_TYPES(input.scalar_type(), "l2norm_kernel", [&] {
l2norm_kernel_impl<scalar_t>(output.data_ptr<scalar_t>(), input.data_ptr<scalar_t>(), batch_size, hidden_size, eps);
});
return output;
}
// input : {batch_size, hidden_size}
// weight: {hidden_size}
at::Tensor rmsnorm_cpu(at::Tensor& input, at::Tensor& weight, double eps) {
RECORD_FUNCTION("sgl-kernel::rmsnorm_cpu", std::vector<c10::IValue>({input, weight}));
CHECK_LAST_DIM_CONTIGUOUS_INPUT(input);
CHECK_INPUT(weight);
CHECK_DIM(2, input);
CHECK_DIM(1, weight);
CHECK_EQ(input.size(1), weight.size(0));
int64_t batch_size = input.size(0);
int64_t hidden_size = input.size(1);
at::Tensor output = at::empty_like(input);
int64_t input_strideN = input.stride(0);
AT_DISPATCH_REDUCED_FLOATING_TYPES(input.scalar_type(), "rmsnorm_kernel", [&] {
using Vec = at::vec::Vectorized<float>;
rmsnorm_kernel_impl<scalar_t>(
output.data_ptr<scalar_t>(),
input.data_ptr<scalar_t>(),
weight.data_ptr<scalar_t>(),
batch_size,
hidden_size,
input_strideN,
[](float x) { return x; },
[](Vec x) { return x; },
eps);
});
return output;
}
// input : {batch_size, hidden_size}
// weight: {hidden_size}
void layernorm_cpu(at::Tensor& input, at::Tensor& weight, double eps) {
RECORD_FUNCTION("sgl-kernel::layernorm_cpu", std::vector<c10::IValue>({input, weight}));
CHECK_LAST_DIM_CONTIGUOUS_INPUT(input);
CHECK_INPUT(weight);
CHECK_DIM(2, input);
CHECK_DIM(1, weight);
CHECK_EQ(input.size(1), weight.size(0));
int64_t batch_size = input.size(0);
int64_t hidden_size = input.size(1);
int64_t input_strideN = input.stride(0);
int64_t num_threads = at::get_num_threads();
at::Tensor buffer = at::empty({num_threads, hidden_size}, input.options().dtype(at::kFloat));
AT_DISPATCH_REDUCED_FLOATING_TYPES(input.scalar_type(), "layernorm_kernel", [&] {
fused_add_layernorm_kernel_impl<scalar_t>(
input.data_ptr<scalar_t>(),
nullptr,
weight.data_ptr<scalar_t>(),
buffer.data_ptr<float>(),
batch_size,
hidden_size,
input_strideN,
eps);
});
}
at::Tensor gemma_rmsnorm_cpu(at::Tensor& input, at::Tensor& weight, double eps) {
RECORD_FUNCTION("sgl-kernel::gemma_rmsnorm_cpu", std::vector<c10::IValue>({input, weight}));
CHECK_LAST_DIM_CONTIGUOUS_INPUT(input);
CHECK_INPUT(weight);
CHECK_DIM(2, input);
CHECK_DIM(1, weight);
CHECK_EQ(input.size(1), weight.size(0));
int64_t batch_size = input.size(0);
int64_t hidden_size = input.size(1);
at::Tensor output = at::empty_like(input);
int64_t input_strideN = input.stride(0);
AT_DISPATCH_REDUCED_FLOATING_TYPES(input.scalar_type(), "gemma_rmsnorm_kernel", [&] {
using Vec = at::vec::Vectorized<float>;
Vec one_vec = Vec(float(1));
rmsnorm_kernel_impl<scalar_t>(
output.data_ptr<scalar_t>(),
input.data_ptr<scalar_t>(),
weight.data_ptr<scalar_t>(),
batch_size,
hidden_size,
input_strideN,
[](float x) { return x + 1; },
[one_vec](Vec x) { return x + one_vec; },
eps);
});
return output;
}
// input : {batch_size, hidden_size} or {batch_size, num_head, seq_len, head_dim}
// weight: {hidden_size}
at::Tensor gemma3_rmsnorm_cpu(at::Tensor& input, at::Tensor& weight, double eps) {
RECORD_FUNCTION("sgl-kernel::gemma3_rmsnorm_cpu", std::vector<c10::IValue>({input, weight}));
CHECK_LAST_DIM_CONTIGUOUS_INPUT(input);
CHECK_INPUT(weight);
TORCH_CHECK(
input.dim() == 2 || input.dim() == 4, "gemma3_rmsnorm_cpu: input must be 2D or 4D, got ", input.dim(), "D");
CHECK_DIM(1, weight);
CHECK_EQ(input.size(-1), weight.size(0));
int64_t batch_size = input.size(0);
int64_t hidden_size = weight.size(0);
at::Tensor output = at::empty_like(input);
if (input.dim() == 2) {
int64_t input_strideN = input.stride(0);
AT_DISPATCH_REDUCED_FLOATING_TYPES(input.scalar_type(), "gemma3_rmsnorm_kernel", [&] {
using Vec = at::vec::Vectorized<float>;
Vec one_vec = Vec(float(1));
rmsnorm_kernel_impl<scalar_t>(
output.data_ptr<scalar_t>(),
input.data_ptr<scalar_t>(),
weight.data_ptr<scalar_t>(),
batch_size,
hidden_size,
input_strideN,
[](float x) { return x + 1; },
[one_vec](Vec x) { return x + one_vec; },
eps);
});
} else {
int64_t input_strideB = input.stride(0);
int64_t input_strideH = input.stride(1);
int64_t input_strideS = input.stride(2);
int64_t output_strideB = output.stride(0);
int64_t output_strideH = output.stride(1);
int64_t output_strideS = output.stride(2);
int64_t num_head = input.size(1);
int64_t seq_len = input.size(2);
AT_DISPATCH_REDUCED_FLOATING_TYPES(input.scalar_type(), "gemma3_rmsnorm_kernel", [&] {
gemma3_rmsnorm_kernel_4d_impl<scalar_t>(
output.data_ptr<scalar_t>(),
input.data_ptr<scalar_t>(),
weight.data_ptr<scalar_t>(),
batch_size,
num_head,
seq_len,
hidden_size,
input_strideB,
input_strideH,
input_strideS,
output_strideB,
output_strideH,
output_strideS,
eps);
});
}
return output;
}
// input : {batch_size, hidden_size}
// weight: {hidden_size}
// gate: {batch_size, hidden_size}
at::Tensor fused_rmsnorm_gated_cpu(at::Tensor& input, at::Tensor& weight, at::Tensor& gate, double eps) {
RECORD_FUNCTION("sgl-kernel::fused_rmsnorm_gated_cpu", std::vector<c10::IValue>({input, weight, gate}));
CHECK_LAST_DIM_CONTIGUOUS_INPUT(input);
CHECK_INPUT(weight);
CHECK_INPUT(gate);
CHECK_DIM(2, input);
CHECK_DIM(1, weight);
CHECK_DIM(2, gate);
CHECK_EQ(input.size(1), weight.size(0));
int64_t batch_size = input.size(0);
int64_t hidden_size = input.size(1);
CHECK_EQ(input.size(0), gate.size(0));
CHECK_EQ(input.size(1), gate.size(1));
at::Tensor output = at::empty_like(input);
int64_t input_strideN = input.stride(0);
AT_DISPATCH_REDUCED_FLOATING_TYPES(input.scalar_type(), "fused_rmsnorm_gated_kernel", [&] {
fused_rmsnorm_gated_kernel_impl<scalar_t>(
output.data_ptr<scalar_t>(),
input.data_ptr<scalar_t>(),
weight.data_ptr<scalar_t>(),
gate.data_ptr<scalar_t>(),
batch_size,
hidden_size,
input_strideN,
eps);
});
return output;
}
// input : {batch_size, hidden_size}
// residual: {batch_size, hidden_size}
// weight : {hidden_size}
void fused_add_rmsnorm_cpu(at::Tensor& input, at::Tensor& residual, at::Tensor& weight, double eps) {
RECORD_FUNCTION("sgl-kernel::fused_add_rmsnorm_cpu", std::vector<c10::IValue>({input, residual, weight}));
CHECK_LAST_DIM_CONTIGUOUS_INPUT(input);
CHECK_INPUT(residual);
CHECK_INPUT(weight);
CHECK_DIM(2, input);
CHECK_DIM(2, residual);
CHECK_DIM(1, weight);
CHECK_EQ(input.size(0), residual.size(0));
CHECK_EQ(input.size(1), residual.size(1));
CHECK_EQ(input.size(1), weight.size(0));
int64_t batch_size = input.size(0);
int64_t hidden_size = input.size(1);
int64_t input_strideN = input.stride(0);
// allocate temp buffer to store x in float32 per thread
// TODO: implement a singleton for context
int64_t num_threads = at::get_num_threads();
at::Tensor buffer = at::empty({num_threads, hidden_size}, input.options().dtype(at::kFloat));
AT_DISPATCH_REDUCED_FLOATING_TYPES(input.scalar_type(), "fused_add_rmsnorm_kernel", [&] {
using Vec = at::vec::Vectorized<float>;
fused_add_rmsnorm_kernel_impl<scalar_t>(
input.data_ptr<scalar_t>(),
residual.data_ptr<scalar_t>(),
weight.data_ptr<scalar_t>(),
buffer.data_ptr<float>(),
batch_size,
hidden_size,
input_strideN,
[](float x) { return x; },
[](Vec x) { return x; },
eps);
});
}
// input : {batch_size, hidden_size}
// residual: {batch_size, hidden_size}
// weight : {hidden_size}
void gemma_fused_add_rmsnorm_cpu(at::Tensor& input, at::Tensor& residual, at::Tensor& weight, double eps) {
RECORD_FUNCTION("sgl-kernel::gemma_fused_add_rmsnorm_cpu", std::vector<c10::IValue>({input, residual, weight}));
CHECK_LAST_DIM_CONTIGUOUS_INPUT(input);
CHECK_INPUT(residual);
CHECK_INPUT(weight);
CHECK_DIM(2, input);
CHECK_DIM(2, residual);
CHECK_DIM(1, weight);
CHECK_EQ(input.size(0), residual.size(0));
CHECK_EQ(input.size(1), residual.size(1));
CHECK_EQ(input.size(1), weight.size(0));
int64_t batch_size = input.size(0);
int64_t hidden_size = input.size(1);
int64_t input_strideN = input.stride(0);
// allocate temp buffer to store x in float32 per thread
// TODO: implement a singleton for context
int64_t num_threads = at::get_num_threads();
at::Tensor buffer = at::empty({num_threads, hidden_size}, input.options().dtype(at::kFloat));
AT_DISPATCH_REDUCED_FLOATING_TYPES(input.scalar_type(), "gemma_fused_add_rmsnorm_kernel", [&] {
using Vec = at::vec::Vectorized<float>;
Vec one_vec = Vec(float(1));
fused_add_rmsnorm_kernel_impl<scalar_t>(
input.data_ptr<scalar_t>(),
residual.data_ptr<scalar_t>(),
weight.data_ptr<scalar_t>(),
buffer.data_ptr<float>(),
batch_size,
hidden_size,
input_strideN,
[](float x) { return x + 1; },
[one_vec](Vec x) { return x + one_vec; },
eps);
});
}
// input : {batch_size, hidden_size}
// residual: {batch_size, hidden_size}
// weight : {hidden_size}
void fused_add_layernorm_cpu(at::Tensor& input, at::Tensor& residual, at::Tensor& weight, double eps) {
RECORD_FUNCTION("sgl-kernel::fused_add_layernorm_cpu", std::vector<c10::IValue>({input, residual, weight}));
CHECK_LAST_DIM_CONTIGUOUS_INPUT(input);
CHECK_INPUT(residual);
CHECK_INPUT(weight);
CHECK_DIM(2, input);
CHECK_DIM(2, residual);
CHECK_DIM(1, weight);
CHECK_EQ(input.size(0), residual.size(0));
CHECK_EQ(input.size(1), residual.size(1));
CHECK_EQ(input.size(1), weight.size(0));
int64_t batch_size = input.size(0);
int64_t hidden_size = input.size(1);
int64_t input_strideN = input.stride(0);
int64_t num_threads = at::get_num_threads();
at::Tensor buffer = at::empty({num_threads, hidden_size}, input.options().dtype(at::kFloat));
AT_DISPATCH_REDUCED_FLOATING_TYPES(input.scalar_type(), "fused_add_layernorm_kernel", [&] {
fused_add_layernorm_kernel_impl<scalar_t>(
input.data_ptr<scalar_t>(),
residual.data_ptr<scalar_t>(),
weight.data_ptr<scalar_t>(),
buffer.data_ptr<float>(),
batch_size,
hidden_size,
input_strideN,
eps);
});
}
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