// Copyright (c) Microsoft Corporation. // SPDX-License-Identifier: Apache-2.0 // DeepSpeed Team /* Copyright NVIDIA/apex This file is adapted from fused adam in NVIDIA/apex, commit a109f85 */ #include #include #include #include // Another possibility: // #include #include #include "multi_tensor_apply.cuh" #include "type_shim.h" #define BLOCK_SIZE 512 #define ILP 4 using MATH_T = float; template struct LionFunctor { __device__ __forceinline__ void operator()(int chunk_size, volatile int* noop_gmem, TensorListMetadata<3>& tl, const float beta1, const float beta2, const float lr, const float decay) { // I'd like this kernel to propagate infs/nans. // if(*noop_gmem == 1) // return; int tensor_loc = tl.block_to_tensor[blockIdx.x]; // potentially use to pass in list of scalar // int tensor_num = tl.start_tensor_this_launch + tensor_loc; int chunk_idx = tl.block_to_chunk[blockIdx.x]; int n = tl.sizes[tensor_loc]; T* g = (T*)tl.addresses[0][tensor_loc]; g += chunk_idx * chunk_size; T* p = (T*)tl.addresses[1][tensor_loc]; p += chunk_idx * chunk_size; T* m = (T*)tl.addresses[2][tensor_loc]; m += chunk_idx * chunk_size; n -= chunk_idx * chunk_size; MATH_T after_decay = 1.0f - lr * decay; // see note in multi_tensor_scale_kernel.cu for (int i_start = 0; i_start < n && i_start < chunk_size; i_start += blockDim.x * ILP) { MATH_T r_g[ILP]; MATH_T r_p[ILP]; MATH_T r_m[ILP]; #pragma unroll for (int ii = 0; ii < ILP; ii++) { int i = i_start + threadIdx.x + ii * blockDim.x; if (i < n && i < chunk_size) { r_g[ii] = g[i]; r_p[ii] = p[i]; r_m[ii] = m[i]; } else { r_g[ii] = MATH_T(0); r_p[ii] = MATH_T(0); r_m[ii] = MATH_T(0); } } #pragma unroll for (int ii = 0; ii < ILP; ii++) { MATH_T c = beta1 * r_m[ii] + (1 - beta1) * r_g[ii]; MATH_T update = c > 0 ? (-lr) : lr; r_p[ii] = r_p[ii] * after_decay + update; r_m[ii] = beta2 * r_m[ii] + (1 - beta2) * r_g[ii]; } #pragma unroll for (int ii = 0; ii < ILP; ii++) { int i = i_start + threadIdx.x + ii * blockDim.x; if (i < n && i < chunk_size) { p[i] = r_p[ii]; m[i] = r_m[ii]; } } } } }; void multi_tensor_lion_cuda(int chunk_size, at::Tensor noop_flag, std::vector> tensor_lists, const float lr, const float beta1, const float beta2, const int step, const float weight_decay) { using namespace at; // Assume single type across p,g,m1,m2 now DISPATCH_DOUBLE_FLOAT_AND_HALF(tensor_lists[0][0].scalar_type(), 0, "lion", multi_tensor_apply<3>(BLOCK_SIZE, chunk_size, noop_flag, tensor_lists, LionFunctor(), beta1, beta2, lr, weight_decay);) AT_CUDA_CHECK(cudaGetLastError()); }