layernorm_kernels_opt.cu

#include <torch/all.h>
#include <ATen/cuda/CUDAContext.h>
#include <c10/cuda/CUDAGuard.h>
#include <ATen/native/cuda/MemoryAccess.cuh>
#include <c10/cuda/CUDAMathCompat.h>
#include <ATen/AccumulateType.h>
#include <THC/THCDeviceUtils.cuh>
#include "../dispatch_utils.h"
#include "../reduction_utils.cuh"
#ifndef USE_ROCM
  #include <cuda_bf16.h>
  #include <cuda_fp16.h>
#else
  #include <hip/hip_bf16.h>
  #include <hip/hip_fp16.h>

using __nv_bfloat16 = __hip_bfloat16;
using __nv_bfloat162 = __hip_bfloat162;
#endif

namespace vllm {

// TODO(woosuk): Further optimize this kernel.
template <typename scalar_t>
__global__ void rms_norm_kernel(
    scalar_t* __restrict__ out,           // [..., hidden_size]
    const scalar_t* __restrict__ input,   // [..., hidden_size]
    const scalar_t* __restrict__ weight,  // [hidden_size]
    const float epsilon, const int num_tokens, const int hidden_size) {
  __shared__ float s_variance;
  float variance = 0.0f;

  for (int idx = threadIdx.x; idx < hidden_size; idx += blockDim.x) {
    const float x = (float)input[blockIdx.x * hidden_size + idx];
    variance += x * x;
  }
  variance = blockReduceSum<float>(variance);
  if (threadIdx.x == 0) {
    s_variance = rsqrtf(variance / hidden_size + epsilon);
  }
  __syncthreads();

  for (int idx = threadIdx.x; idx < hidden_size; idx += blockDim.x) {
    float x = (float)input[blockIdx.x * hidden_size + idx];
    out[blockIdx.x * hidden_size + idx] =
        ((scalar_t)(x * s_variance)) * weight[idx];
  }
}

/* Converter structs for the conversion from torch types to HIP/CUDA types,
   and the associated type conversions within HIP/CUDA. These helpers need
   to be implemented for now because the relevant type conversion
   operators/constructors are not consistently implemented by HIP/CUDA, so
   a generic conversion via type casts cannot be implemented.

   Each struct should have the member static constexpr bool `exists`:
   If false, the optimized kernel is not used for the corresponding torch type.
   If true, the struct should be fully defined as shown in the examples below.
 */
template <typename torch_type>
struct _typeConvert {
  static constexpr bool exists = false;
};

#if defined(USE_ROCM) || (defined(CUDA_VERSION) && (CUDA_VERSION >= 12000))
// CUDA < 12.0 runs into issues with packed type conversion
template <>
struct _typeConvert<c10::Half> {
  static constexpr bool exists = true;
  using hip_type = __half;
  using packed_hip_type = __half2;

  __device__ static inline float convert(hip_type x) { return __half2float(x); }
  __device__ static inline float2 convert(packed_hip_type x) {
    return __half22float2(x);
  }
  __device__ static inline hip_type convert(float x) {
    return __float2half_rn(x);
  }
  __device__ static inline packed_hip_type convert(float2 x) {
    return __float22half2_rn(x);
  }
};

  #if defined(__CUDA_ARCH__) && __CUDA_ARCH__ >= 800
// CUDA_ARCH < 800 does not have BF16 support
// TODO: Add in ROCm support once public headers handle bf16 maturely
template <>
struct _typeConvert<c10::BFloat16> {
  static constexpr bool exists = true;
  using hip_type = __nv_bfloat16;
  using packed_hip_type = __nv_bfloat162;

  __device__ static inline float convert(hip_type x) {
    return __bfloat162float(x);
  }
  __device__ static inline float2 convert(packed_hip_type x) {
    return __bfloat1622float2(x);
  }
  __device__ static inline hip_type convert(float x) {
    return __float2bfloat16(x);
  }
  __device__ static inline packed_hip_type convert(float2 x) {
    return __float22bfloat162_rn(x);
  }
};
  #endif  // defined(__CUDA_ARCH__) && __CUDA_ARCH__ >= 800
#endif    // defined(USE_ROCM) || (defined(CUDA_VERSION) && (CUDA_VERSION >=
          // 12000))

/* Vector POD struct to generate vectorized and packed FP16/BF16 ops
   for appropriate specializations of fused_add_rms_norm_kernel.
   Only functions that are necessary in that kernel are implemented.
   Alignment to 16 bytes is required to use 128-bit global memory ops.
 */
template <typename scalar_t, int width>
struct alignas(16) _f16Vec {
  /* Not theoretically necessary that width is a power of 2 but should
     almost always be the case for optimization purposes */
  static_assert(width > 0 && (width & (width - 1)) == 0,
                "Width is not a positive power of 2!");
  using Converter = _typeConvert<scalar_t>;
  using T1 = typename Converter::hip_type;
  using T2 = typename Converter::packed_hip_type;
  T1 data[width];

  __device__ _f16Vec& operator+=(const _f16Vec<scalar_t, width>& other) {
    if constexpr (width % 2 == 0) {
#pragma unroll
      for (int i = 0; i < width; i += 2) {
        T2 temp{data[i], data[i + 1]};
        temp += T2{other.data[i], other.data[i + 1]};
        data[i] = temp.x;
        data[i + 1] = temp.y;
      }
    } else {
#pragma unroll
      for (int i = 0; i < width; ++i) data[i] += other.data[i];
    }
    return *this;
  }

  __device__ _f16Vec& operator*=(const _f16Vec<scalar_t, width>& other) {
    if constexpr (width % 2 == 0) {
#pragma unroll
      for (int i = 0; i < width; i += 2) {
        T2 temp{data[i], data[i + 1]};
        temp *= T2{other.data[i], other.data[i + 1]};
        data[i] = temp.x;
        data[i + 1] = temp.y;
      }
    } else {
#pragma unroll
      for (int i = 0; i < width; ++i) data[i] *= other.data[i];
    }
    return *this;
  }

  __device__ _f16Vec& operator*=(const float scale) {
    if constexpr (width % 2 == 0) {
#pragma unroll
      for (int i = 0; i < width; i += 2) {
        float2 temp_f = Converter::convert(T2{data[i], data[i + 1]});
        temp_f.x *= scale;
        temp_f.y *= scale;
        T2 temp = Converter::convert(temp_f);
        data[i] = temp.x;
        data[i + 1] = temp.y;
      }
    } else {
#pragma unroll
      for (int i = 0; i < width; ++i) {
        float temp = Converter::convert(data[i]) * scale;
        data[i] = Converter::convert(temp);
      }
    }
    return *this;
  }

  __device__ float sum_squares() const {
    float result = 0.0f;
    if constexpr (width % 2 == 0) {
#pragma unroll
      for (int i = 0; i < width; i += 2) {
        float2 z = Converter::convert(T2{data[i], data[i + 1]});
        result += z.x * z.x + z.y * z.y;
      }
    } else {
#pragma unroll
      for (int i = 0; i < width; ++i) {
        float x = Converter::convert(data[i]);
        result += x * x;
      }
    }
    return result;
  }
};

/* Function specialization in the case of FP16/BF16 tensors.
   Additional optimizations we can make in this case are
   packed and vectorized operations, which help with the
   memory latency bottleneck. */
template <typename scalar_t, int width>
__global__ std::enable_if_t<(width > 0) && _typeConvert<scalar_t>::exists>
fused_add_rms_norm_kernel(
    scalar_t* __restrict__ input,         // [..., hidden_size]
    scalar_t* __restrict__ residual,      // [..., hidden_size]
    const scalar_t* __restrict__ weight,  // [hidden_size]
    const float epsilon, const int num_tokens, const int hidden_size) {
  // Sanity checks on our vector struct and type-punned pointer arithmetic
  static_assert(std::is_pod_v<_f16Vec<scalar_t, width>>);
  static_assert(sizeof(_f16Vec<scalar_t, width>) == sizeof(scalar_t) * width);

  const int vec_hidden_size = hidden_size / width;
  __shared__ float s_variance;
  float variance = 0.0f;
  /* These and the argument pointers are all declared `restrict` as they are
     not aliased in practice. Argument pointers should not be dereferenced
     in this kernel as that would be undefined behavior */
  auto* __restrict__ input_v =
      reinterpret_cast<_f16Vec<scalar_t, width>*>(input);
  auto* __restrict__ residual_v =
      reinterpret_cast<_f16Vec<scalar_t, width>*>(residual);
  auto* __restrict__ weight_v =
      reinterpret_cast<const _f16Vec<scalar_t, width>*>(weight);

  for (int idx = threadIdx.x; idx < vec_hidden_size; idx += blockDim.x) {
    int id = blockIdx.x * vec_hidden_size + idx;
    _f16Vec<scalar_t, width> temp = input_v[id];
    temp += residual_v[id];
    variance += temp.sum_squares();
    residual_v[id] = temp;
  }
  /* Keep the following if-else block in sync with the
     calculation of max_block_size in fused_add_rms_norm */
  if (num_tokens < 256) {
    variance = blockReduceSum<float, 1024>(variance);
  } else
    variance = blockReduceSum<float, 256>(variance);
  if (threadIdx.x == 0) {
    s_variance = rsqrtf(variance / hidden_size + epsilon);
  }
  __syncthreads();

  for (int idx = threadIdx.x; idx < vec_hidden_size; idx += blockDim.x) {
    int id = blockIdx.x * vec_hidden_size + idx;
    _f16Vec<scalar_t, width> temp = residual_v[id];
    temp *= s_variance;
    temp *= weight_v[idx];
    input_v[id] = temp;
  }
}

/* Generic fused_add_rms_norm_kernel
   The width field is not used here but necessary for other specializations.
 */
template <typename scalar_t, int width>
__global__ std::enable_if_t<(width == 0) || !_typeConvert<scalar_t>::exists>
fused_add_rms_norm_kernel(
    scalar_t* __restrict__ input,         // [..., hidden_size]
    scalar_t* __restrict__ residual,      // [..., hidden_size]
    const scalar_t* __restrict__ weight,  // [hidden_size]
    const float epsilon, const int num_tokens, const int hidden_size) {
  __shared__ float s_variance;
  float variance = 0.0f;

  for (int idx = threadIdx.x; idx < hidden_size; idx += blockDim.x) {
    scalar_t z = input[blockIdx.x * hidden_size + idx];
    z += residual[blockIdx.x * hidden_size + idx];
    float x = (float)z;
    variance += x * x;
    residual[blockIdx.x * hidden_size + idx] = z;
  }
  /* Keep the following if-else block in sync with the
     calculation of max_block_size in fused_add_rms_norm */
  if (num_tokens < 256) {
    variance = blockReduceSum<float, 1024>(variance);
  } else
    variance = blockReduceSum<float, 256>(variance);
  if (threadIdx.x == 0) {
    s_variance = rsqrtf(variance / hidden_size + epsilon);
  }
  __syncthreads();

  for (int idx = threadIdx.x; idx < hidden_size; idx += blockDim.x) {
    float x = (float)residual[blockIdx.x * hidden_size + idx];
    input[blockIdx.x * hidden_size + idx] =
        ((scalar_t)(x * s_variance)) * weight[idx];
  }
}

}  // namespace vllm

template <typename T,int reducesize=C10_WARP_SIZE>
__inline__ __device__ T WarpReduceSum_NEW(T val) {
#pragma unroll
  for (int offset = reducesize/2; offset > 0; offset >>= 1) {
    val += WARP_SHFL_DOWN(val, offset);
  }
  return val;
}

template <typename T,int block_size=512>
__inline__ __device__ T BlockReduceSum_NEW(T val, T* shared) {
  constexpr int share_size=block_size/C10_WARP_SIZE;
  val = WarpReduceSum_NEW<T>(val);
  if constexpr(block_size==C10_WARP_SIZE)
  {
    return val;
  }
  else{
    const int lid = threadIdx.x % C10_WARP_SIZE;
    const int wid = threadIdx.x / C10_WARP_SIZE;
    if (lid == 0&&wid<share_size) {
      shared[wid] = val;
    }
    __syncthreads();
    if (wid == 0&&lid<share_size) {
      val = WarpReduceSum_NEW<T,share_size>(shared[lid]);
    }
    return val;
  }
}

template <typename scalar_t,typename T_ACC,int Vec=4,int block_size=512>
__global__ void fused_add_rms_kernel_opt(scalar_t* input,scalar_t* residual,scalar_t* gamma,int cols,T_ACC eps)
{
  constexpr int share_size=block_size/C10_WARP_SIZE;
  __shared__ T_ACC val_shared[share_size];
  __shared__ T_ACC s_rstd;
  T_ACC val=0;
  int i=blockIdx.x;
  int j=threadIdx.x;
  int tcol=cols/Vec;
  using LoadT = at::native::memory::aligned_vector<scalar_t, Vec>;
  scalar_t intput_vec[Vec];
  scalar_t residual_vec[Vec];
  T_ACC trstd;
  int idx = i * tcol + j;
  idx*=Vec;
  *(LoadT*)intput_vec = *(LoadT*)(input+idx);
  *(LoadT*)residual_vec = *(LoadT*)(residual+idx);
  if (j < tcol) {
    #pragma unroll
    for (int ii = 0; ii < Vec; ii++) {
      residual_vec[ii]+=intput_vec[ii];
      val += static_cast<T_ACC>(residual_vec[ii])*static_cast<T_ACC>(residual_vec[ii]);
    }
  }
  val = BlockReduceSum_NEW<T_ACC,block_size>(val,val_shared);
  if (j == 0) s_rstd=c10::cuda::compat::rsqrt(val/cols + eps);
  __syncthreads();
  trstd=s_rstd;
  if (j < tcol) {
    #pragma unroll
    for(int ii=0;ii<Vec;ii++){
      int jj=j*Vec+ii;
      intput_vec[ii] = static_cast<T_ACC>(residual_vec[ii]) *trstd* static_cast<T_ACC>(gamma[jj]);
    }
    *(LoadT*)(residual+idx)=*(LoadT*)residual_vec;
    *(LoadT*)(input+idx)=*(LoadT*)intput_vec;
  }
}

template <typename scalar_t,typename T_ACC,int Vec=4,int block_size=512>
__global__ void fused_rms_kernel_opt(scalar_t* input,scalar_t* output,scalar_t* gamma,int cols,T_ACC eps)
{
  constexpr int share_size=block_size/C10_WARP_SIZE;
  __shared__ T_ACC val_shared[share_size];
  __shared__ T_ACC s_rstd;
  T_ACC val=0;
  int i=blockIdx.x;
  int j=threadIdx.x;
  int tcol=cols/Vec;
  using LoadT = at::native::memory::aligned_vector<scalar_t, Vec>;
  scalar_t intput_vec[Vec];
  T_ACC trstd;
  int idx = i * tcol + j;
  idx*=Vec;
  *(LoadT*)intput_vec = *(LoadT*)(input+idx);
  if (j < tcol) {
    #pragma unroll
    for (int ii = 0; ii < Vec; ii++) {
      val += static_cast<T_ACC>(intput_vec[ii])*static_cast<T_ACC>(intput_vec[ii]);
    }
  }
  val = BlockReduceSum_NEW<T_ACC,block_size>(val,val_shared);
  if (j == 0) s_rstd=c10::cuda::compat::rsqrt(val/cols + eps);
  __syncthreads();
  trstd=s_rstd;
  if (j < tcol) {
    #pragma unroll
    for(int ii=0;ii<Vec;ii++){
      int jj=j*Vec+ii;
      intput_vec[ii] = static_cast<T_ACC>(intput_vec[ii]) *trstd* static_cast<T_ACC>(gamma[jj]);
    }
    *(LoadT*)(output+idx)=*(LoadT*)intput_vec;
  }
}

void rms_norm_opt(torch::Tensor& out,     // [..., hidden_size]
              torch::Tensor& input,   // [..., hidden_size]
              torch::Tensor& weight,  // [hidden_size]
              double epsilon) {
  int hidden_size = input.size(-1);
  int num_tokens = input.numel() / hidden_size;
  const at::cuda::OptionalCUDAGuard device_guard(device_of(input));
  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
  auto inp_ptr = reinterpret_cast<std::uintptr_t>(input.data_ptr());
  auto wt_ptr = reinterpret_cast<std::uintptr_t>(weight.data_ptr());
  bool ptrs_are_aligned =inp_ptr % 16 == 0  && wt_ptr % 16 == 0;
  if(hidden_size%16==0&&hidden_size<=16384&&ptrs_are_aligned){
  AT_DISPATCH_FLOATING_TYPES_AND2(
    at::ScalarType::Half,
    at::ScalarType::BFloat16,
    input.scalar_type(),
    "fused_add_rms_norm_kernel",
    [&] {
      using T_ACC = at::acc_type<scalar_t, true>;
      T_ACC eps = epsilon;
      scalar_t* self_data = input.data_ptr<scalar_t>();
      scalar_t* out_data =out.data_ptr<scalar_t>();
      scalar_t* weight_data=weight.data_ptr<scalar_t>();
      if (hidden_size<=1024){
          fused_rms_kernel_opt<scalar_t,T_ACC,8,128><<<num_tokens,  128, 0, stream>>>(self_data,out_data,weight_data,hidden_size,eps);
      }
      else if(hidden_size<=2048){
          fused_rms_kernel_opt<scalar_t,T_ACC,8,256><<<num_tokens,  256, 0, stream>>>(self_data,out_data,weight_data,hidden_size,eps);
      }
      else if(hidden_size<=4096){
          if(num_tokens>1200){
            fused_rms_kernel_opt<scalar_t,T_ACC,8,512><<<num_tokens,  512, 0, stream>>>(self_data,out_data,weight_data,hidden_size,eps);
          }
          else{
            fused_rms_kernel_opt<scalar_t,T_ACC,4,1024><<<num_tokens,  1024, 0, stream>>>(self_data,out_data,weight_data,hidden_size,eps);
          }
      }
      else if(hidden_size<=8192){
           fused_rms_kernel_opt<scalar_t,T_ACC,8,1024><<<num_tokens,  1024, 0, stream>>>(self_data,out_data,weight_data,hidden_size,eps);
      }
      else{
          fused_rms_kernel_opt<scalar_t,T_ACC,16,1024><<<num_tokens,  1024, 0, stream>>>(self_data,out_data,weight_data,hidden_size,eps);
      } 
    });
  }
  else{
    dim3 grid(num_tokens);
    dim3 block(std::min(hidden_size, 1024));
  
    VLLM_DISPATCH_FLOATING_TYPES(input.scalar_type(), "rms_norm_kernel", [&] {
      vllm::rms_norm_kernel<scalar_t><<<grid, block, 0, stream>>>(
          out.data_ptr<scalar_t>(), input.data_ptr<scalar_t>(),
          weight.data_ptr<scalar_t>(), epsilon, num_tokens, hidden_size);
    });
  }
}

#define LAUNCH_FUSED_ADD_RMS_NORM(width)                                       \
  VLLM_DISPATCH_FLOATING_TYPES(                                                \
      input.scalar_type(), "fused_add_rms_norm_kernel", [&] {                  \
        vllm::fused_add_rms_norm_kernel<scalar_t, width>                       \
            <<<grid, block, 0, stream>>>(input.data_ptr<scalar_t>(),           \
                                         residual.data_ptr<scalar_t>(),        \
                                         weight.data_ptr<scalar_t>(), epsilon, \
                                         num_tokens, hidden_size);             \
      });



void fused_add_rms_norm_opt(torch::Tensor& input,     // [..., hidden_size]
                        torch::Tensor& residual,  // [..., hidden_size]
                        torch::Tensor& weight,    // [hidden_size]
                        double epsilon) {
  int hidden_size = input.size(-1);
  int num_tokens = input.numel() / hidden_size;
  const at::cuda::OptionalCUDAGuard device_guard(device_of(input));
  const cudaStream_t stream = at::cuda::getCurrentCUDAStream();
  auto inp_ptr = reinterpret_cast<std::uintptr_t>(input.data_ptr());
  auto res_ptr = reinterpret_cast<std::uintptr_t>(residual.data_ptr());
  auto wt_ptr = reinterpret_cast<std::uintptr_t>(weight.data_ptr());
  bool ptrs_are_aligned =inp_ptr % 16 == 0 && res_ptr % 16 == 0 && wt_ptr % 16 == 0;
  if(hidden_size%16==0&&hidden_size>=2048&&hidden_size<=8192&&ptrs_are_aligned){
    AT_DISPATCH_FLOATING_TYPES_AND2(
      at::ScalarType::Half,
      at::ScalarType::BFloat16,
      input.scalar_type(),
      "fused_add_rms_norm_kernel",
      [&] {
        using T_ACC = at::acc_type<scalar_t, true>;
        T_ACC eps = epsilon;
        scalar_t* self_data = input.data_ptr<scalar_t>();
        scalar_t* other_data =residual.data_ptr<scalar_t>();
        scalar_t* weight_data=weight.data_ptr<scalar_t>();
        if (hidden_size<=1024){
            fused_add_rms_kernel_opt<scalar_t,T_ACC,8,128><<<num_tokens,  128, 0, stream>>>(self_data,other_data,weight_data,hidden_size,eps);
        }
        else if(hidden_size<=2048){
            fused_add_rms_kernel_opt<scalar_t,T_ACC,8,256><<<num_tokens,  256, 0, stream>>>(self_data,other_data,weight_data,hidden_size,eps);
        }
        else if(hidden_size<=4096){
            if(num_tokens>1200){
              fused_add_rms_kernel_opt<scalar_t,T_ACC,8,512><<<num_tokens,  512, 0, stream>>>(self_data,other_data,weight_data,hidden_size,eps);
            }
            else{
              fused_add_rms_kernel_opt<scalar_t,T_ACC,4,1024><<<num_tokens,  1024, 0, stream>>>(self_data,other_data,weight_data,hidden_size,eps);
            }
        }
        else if(hidden_size<=8192){
            fused_add_rms_kernel_opt<scalar_t,T_ACC,8,1024><<<num_tokens,  1024, 0, stream>>>(self_data,other_data,weight_data,hidden_size,eps);
        }
        else{
            fused_add_rms_kernel_opt<scalar_t,T_ACC,16,1024><<<num_tokens,  1024, 0, stream>>>(self_data,other_data,weight_data,hidden_size,eps);
        } 
      });
  }
  else{
    dim3 grid(num_tokens);
    /* This kernel is memory-latency bound in many scenarios.
      When num_tokens is large, a smaller block size allows
      for increased block occupancy on CUs and better latency
      hiding on global mem ops. */
    const int max_block_size = (num_tokens < 256) ? 1024 : 256;
    dim3 block(std::min(hidden_size, max_block_size));
    /*If the tensor types are FP16/BF16, try to use the optimized kernel
      with packed + vectorized ops.
      Max optimization is achieved with a width-8 vector of FP16/BF16s
      since we can load at most 128 bits at once in a global memory op.
      However, this requires each tensor's data to be aligned to 16
      bytes.
    */

    if (ptrs_are_aligned && hidden_size % 8 == 0) {
      LAUNCH_FUSED_ADD_RMS_NORM(8);
    } else {
      LAUNCH_FUSED_ADD_RMS_NORM(0);
    }
  }
}