| #include <ATen/ATen.h> |
| #include <ATen/AccumulateType.h> |
| #include <ATen/cuda/CUDAContext.h> |
| #include <ATen/cuda/Exceptions.h> |
| |
| |
|
|
| #include <assert.h> |
|
|
| #include "type_shim.h" |
| #include "multi_tensor_apply.cuh" |
|
|
| #define BLOCK_SIZE 512 |
| #define ILP 4 |
|
|
| typedef enum{ |
| ADAM_MODE_0 =0, |
| ADAM_MODE_1 =1 |
| } adamMode_t; |
|
|
| using MATH_T = float; |
|
|
| template<typename T, typename FULL_T, typename index_t> |
| struct AdamFunctor |
| { |
| __device__ __forceinline__ void operator()( |
| index_t chunk_size, |
| volatile int* noop_gmem, |
| TensorListMetadata<4>& tl, |
| const float beta1, |
| const float beta2, |
| const float beta1_correction, |
| const float beta2_correction, |
| const float epsilon, |
| const float lr, |
| adamMode_t mode, |
| const float decay) |
| { |
| |
| |
| |
|
|
| index_t tensor_loc = tl.block_to_tensor[blockIdx.x]; |
|
|
| |
| |
|
|
| index_t chunk_idx = tl.block_to_chunk[blockIdx.x]; |
| index_t 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; |
|
|
| FULL_T* m = (FULL_T*)tl.addresses[2][tensor_loc]; |
| m += chunk_idx*chunk_size; |
|
|
| FULL_T* v = (FULL_T*)tl.addresses[3][tensor_loc]; |
| v += chunk_idx*chunk_size; |
|
|
| n -= chunk_idx*chunk_size; |
|
|
| |
| for(index_t 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]; |
| MATH_T r_v[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]; |
| r_v[ii] = v[i]; |
| } else { |
| r_g[ii] = MATH_T(0); |
| r_p[ii] = MATH_T(0); |
| r_m[ii] = MATH_T(0); |
| r_v[ii] = MATH_T(0); |
| } |
| } |
| #pragma unroll |
| for(int ii = 0; ii < ILP; ii++) |
| { |
| if(mode == ADAM_MODE_0) { |
| r_g[ii] = r_g[ii] + (decay * r_p[ii]); |
| r_m[ii] = beta1 * r_m[ii] + (1-beta1) * r_g[ii]; |
| r_v[ii] = beta2 * r_v[ii] + (1-beta2) * r_g[ii] * r_g[ii]; |
| MATH_T next_m_unbiased = r_m[ii] / beta1_correction; |
| MATH_T next_v_unbiased = r_v[ii] / beta2_correction; |
| MATH_T denom = sqrtf(next_v_unbiased) + epsilon; |
| MATH_T update = next_m_unbiased / denom; |
| r_p[ii] = r_p[ii] - (lr * update); |
| } |
| else { |
| r_m[ii] = beta1 * r_m[ii] + (1-beta1) * r_g[ii]; |
| r_v[ii] = beta2 * r_v[ii] + (1-beta2) * r_g[ii] * r_g[ii]; |
| MATH_T next_m_unbiased = r_m[ii] / beta1_correction; |
| MATH_T next_v_unbiased = r_v[ii] / beta2_correction; |
| MATH_T denom = sqrtf(next_v_unbiased) + epsilon; |
| MATH_T update = (next_m_unbiased / denom) + (decay * r_p[ii]); |
| r_p[ii] = r_p[ii] - (lr * update); |
| } |
| } |
| #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]; |
| v[i] = r_v[ii]; |
| } |
| } |
| } |
| } |
| }; |
|
|
| template<typename T, typename FULL_T> |
| struct AdamCapturableFunctor |
| { |
| __device__ __forceinline__ void operator()( |
| int chunk_size, |
| volatile int* noop_gmem, |
| TensorListMetadata<4>& tl, |
| const float beta1, |
| const float beta2, |
| const int* step, |
| const int bias_correction, |
| const float epsilon, |
| const float* lr, |
| adamMode_t mode, |
| const float decay, |
| const float* inv_scale) |
| { |
| if(*noop_gmem == 1) |
| return; |
|
|
| float beta1_correction = 1.0f, beta2_correction = 1.0f; |
| if (bias_correction == 1) { |
| beta1_correction = 1 - pow(beta1, *step); |
| beta2_correction = 1 - pow(beta2, *step); |
| } |
|
|
| int tensor_loc = tl.block_to_tensor[blockIdx.x]; |
|
|
| |
| |
|
|
| 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; |
|
|
| FULL_T* m = (FULL_T*)tl.addresses[2][tensor_loc]; |
| m += chunk_idx*chunk_size; |
|
|
| FULL_T* v = (FULL_T*)tl.addresses[3][tensor_loc]; |
| v += chunk_idx*chunk_size; |
|
|
| n -= chunk_idx*chunk_size; |
|
|
| |
| 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]; |
| MATH_T r_v[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] = static_cast<MATH_T>(g[i]) * (*inv_scale); |
| g[i] = static_cast<T>(r_g[ii]); |
| r_p[ii] = static_cast<MATH_T>(p[i]); |
| r_m[ii] = static_cast<MATH_T>(m[i]); |
| r_v[ii] = static_cast<MATH_T>(v[i]); |
| } else { |
| r_g[ii] = MATH_T(0); |
| r_p[ii] = MATH_T(0); |
| r_m[ii] = MATH_T(0); |
| r_v[ii] = MATH_T(0); |
| } |
| } |
| #pragma unroll |
| for(int ii = 0; ii < ILP; ii++) |
| { |
| if(mode == ADAM_MODE_0) { |
| r_g[ii] = r_g[ii] + (decay * r_p[ii]); |
| r_m[ii] = beta1 * r_m[ii] + (1-beta1) * r_g[ii]; |
| r_v[ii] = beta2 * r_v[ii] + (1-beta2) * r_g[ii] * r_g[ii]; |
| MATH_T next_m_unbiased = r_m[ii] / beta1_correction; |
| MATH_T next_v_unbiased = r_v[ii] / beta2_correction; |
| MATH_T denom = sqrtf(next_v_unbiased) + epsilon; |
| MATH_T update = next_m_unbiased / denom; |
| r_p[ii] = r_p[ii] - (*lr * update); |
| } |
| else { |
| r_m[ii] = beta1 * r_m[ii] + (1-beta1) * r_g[ii]; |
| r_v[ii] = beta2 * r_v[ii] + (1-beta2) * r_g[ii] * r_g[ii]; |
| MATH_T next_m_unbiased = r_m[ii] / beta1_correction; |
| MATH_T next_v_unbiased = r_v[ii] / beta2_correction; |
| MATH_T denom = sqrtf(next_v_unbiased) + epsilon; |
| MATH_T update = (next_m_unbiased / denom) + (decay * r_p[ii]); |
| r_p[ii] = r_p[ii] - (*lr * update); |
| } |
| } |
| #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] = static_cast<T>(r_p[ii]); |
| m[i] = static_cast<T>(r_m[ii]); |
| v[i] = static_cast<T>(r_v[ii]); |
| } |
| } |
| } |
| } |
| }; |
|
|
| template<typename T, typename FULL_T> |
| struct AdamCapturableMasterFunctor |
| { |
| __device__ __forceinline__ void operator()( |
| int chunk_size, |
| volatile int* noop_gmem, |
| TensorListMetadata<5>& tl, |
| const float beta1, |
| const float beta2, |
| const int* step, |
| const int bias_correction, |
| const float epsilon, |
| const float* lr, |
| adamMode_t mode, |
| const float decay, |
| const float* inv_scale) |
| { |
| if(*noop_gmem == 1) |
| return; |
|
|
| float beta1_correction = 1.0f, beta2_correction = 1.0f; |
| if (bias_correction == 1) { |
| beta1_correction = 1 - pow(beta1, *step); |
| beta2_correction = 1 - pow(beta2, *step); |
| } |
|
|
| int tensor_loc = tl.block_to_tensor[blockIdx.x]; |
|
|
| |
| |
|
|
| 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; |
|
|
| FULL_T* m = (FULL_T*)tl.addresses[2][tensor_loc]; |
| m += chunk_idx*chunk_size; |
|
|
| FULL_T* v = (FULL_T*)tl.addresses[3][tensor_loc]; |
| v += chunk_idx*chunk_size; |
|
|
| FULL_T* p_master = (FULL_T*)tl.addresses[4][tensor_loc]; |
| p_master += chunk_idx*chunk_size; |
|
|
| n -= chunk_idx*chunk_size; |
|
|
| |
| 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]; |
| MATH_T r_v[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] = static_cast<MATH_T>(g[i]) * (*inv_scale); |
| g[i] = static_cast<T>(r_g[ii]); |
| r_p[ii] = static_cast<MATH_T>(p_master[i]); |
| r_m[ii] = static_cast<MATH_T>(m[i]); |
| r_v[ii] = static_cast<MATH_T>(v[i]); |
| } else { |
| r_g[ii] = MATH_T(0); |
| r_p[ii] = MATH_T(0); |
| r_m[ii] = MATH_T(0); |
| r_v[ii] = MATH_T(0); |
| } |
| } |
| #pragma unroll |
| for(int ii = 0; ii < ILP; ii++) |
| { |
| if(mode == ADAM_MODE_0) { |
| r_g[ii] = r_g[ii] + (decay * r_p[ii]); |
| r_m[ii] = beta1 * r_m[ii] + (1-beta1) * r_g[ii]; |
| r_v[ii] = beta2 * r_v[ii] + (1-beta2) * r_g[ii] * r_g[ii]; |
| MATH_T next_m_unbiased = r_m[ii] / beta1_correction; |
| MATH_T next_v_unbiased = r_v[ii] / beta2_correction; |
| MATH_T denom = sqrtf(next_v_unbiased) + epsilon; |
| MATH_T update = next_m_unbiased / denom; |
| r_p[ii] = r_p[ii] - (*lr * update); |
| } |
| else { |
| r_m[ii] = beta1 * r_m[ii] + (1-beta1) * r_g[ii]; |
| r_v[ii] = beta2 * r_v[ii] + (1-beta2) * r_g[ii] * r_g[ii]; |
| MATH_T next_m_unbiased = r_m[ii] / beta1_correction; |
| MATH_T next_v_unbiased = r_v[ii] / beta2_correction; |
| MATH_T denom = sqrtf(next_v_unbiased) + epsilon; |
| MATH_T update = (next_m_unbiased / denom) + (decay * r_p[ii]); |
| r_p[ii] = r_p[ii] - (*lr * update); |
| } |
| } |
| #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] = static_cast<T>(r_p[ii]); |
| p_master[i] = static_cast<FULL_T>(r_p[ii]); |
| m[i] = static_cast<FULL_T>(r_m[ii]); |
| v[i] = static_cast<FULL_T>(r_v[ii]); |
| } |
| } |
| } |
| } |
| }; |
|
|
| void multi_tensor_adam_cuda( |
| int chunk_size, |
| at::Tensor noop_flag, |
| std::vector<std::vector<at::Tensor>> tensor_lists, |
| const float lr, |
| const float beta1, |
| const float beta2, |
| const float epsilon, |
| const int step, |
| const int mode, |
| const int bias_correction, |
| const float weight_decay) |
| { |
| using namespace at; |
|
|
| |
| float bias_correction1 = 1.0f, bias_correction2 = 1.0f; |
| if (bias_correction == 1) { |
| bias_correction1 = 1 - std::pow(beta1, step); |
| bias_correction2 = 1 - std::pow(beta2, step); |
| } |
|
|
| size_t max_size = 0; |
| bool requires_64bit_indexing = false; |
| for (auto it = tensor_lists.begin(); it != tensor_lists.end(); it++) { |
| for (auto it2 = it->begin(); it2 != it->end(); it2++) { |
| if (it2->numel() > max_size) { |
| max_size = it2->numel(); |
| if (max_size >= INT_MAX) { |
| requires_64bit_indexing = true; |
| break; |
| } |
| } |
| } |
| if (requires_64bit_indexing) { |
| break; |
| } |
| } |
|
|
| if (requires_64bit_indexing) { |
| |
| DISPATCH_DOUBLE_FLOAT_HALF_AND_BFLOAT( |
| tensor_lists[0][0].scalar_type(), 0, "adam", |
| multi_tensor_apply<4>( |
| (int64_t) BLOCK_SIZE, |
| (int64_t) chunk_size, |
| noop_flag, |
| tensor_lists, |
| AdamFunctor<scalar_t_0, float, int64_t>(), |
| beta1, |
| beta2, |
| bias_correction1, |
| bias_correction2, |
| epsilon, |
| lr, |
| (adamMode_t) mode, |
| weight_decay); ) |
| } else { |
| |
| DISPATCH_DOUBLE_FLOAT_HALF_AND_BFLOAT( |
| tensor_lists[0][0].scalar_type(), 0, "adam", |
| multi_tensor_apply<4>( |
| BLOCK_SIZE, |
| chunk_size, |
| noop_flag, |
| tensor_lists, |
| AdamFunctor<scalar_t_0, float, int32_t>(), |
| beta1, |
| beta2, |
| bias_correction1, |
| bias_correction2, |
| epsilon, |
| lr, |
| (adamMode_t) mode, |
| weight_decay); ) |
| } |
| AT_CUDA_CHECK(cudaGetLastError()); |
| } |
|
|
| void multi_tensor_adam_capturable_cuda( |
| int chunk_size, |
| at::Tensor noop_flag, |
| std::vector<std::vector<at::Tensor>> tensor_lists, |
| at::Tensor lr, |
| const float beta1, |
| const float beta2, |
| const float epsilon, |
| at::Tensor step, |
| const int mode, |
| const int bias_correction, |
| const float weight_decay, |
| at::Tensor inv_scale) |
| { |
| using namespace at; |
|
|
| DISPATCH_DOUBLE_FLOAT_HALF_AND_BFLOAT( |
| tensor_lists[0][0].scalar_type(), 0, "adam", |
| multi_tensor_apply<4>( |
| BLOCK_SIZE, |
| chunk_size, |
| noop_flag, |
| tensor_lists, |
| AdamCapturableFunctor<scalar_t_0, float>(), |
| beta1, |
| beta2, |
| step.data_ptr<int>(), |
| bias_correction, |
| epsilon, |
| lr.data_ptr<float>(), |
| (adamMode_t) mode, |
| weight_decay, |
| inv_scale.data_ptr<float>()); ) |
|
|
| AT_CUDA_CHECK(cudaGetLastError()); |
|
|
| } |
|
|
| void multi_tensor_adam_capturable_master_cuda( |
| int chunk_size, |
| at::Tensor noop_flag, |
| std::vector<std::vector<at::Tensor>> tensor_lists, |
| at::Tensor lr, |
| const float beta1, |
| const float beta2, |
| const float epsilon, |
| at::Tensor step, |
| const int mode, |
| const int bias_correction, |
| const float weight_decay, |
| at::Tensor inv_scale) |
| { |
| using namespace at; |
|
|
| DISPATCH_DOUBLE_FLOAT_HALF_AND_BFLOAT( |
| tensor_lists[0][0].scalar_type(), 0, "adam", |
| multi_tensor_apply<5>( |
| BLOCK_SIZE, |
| chunk_size, |
| noop_flag, |
| tensor_lists, |
| AdamCapturableMasterFunctor<scalar_t_0, float>(), |
| beta1, |
| beta2, |
| step.data_ptr<int>(), |
| bias_correction, |
| epsilon, |
| lr.data_ptr<float>(), |
| (adamMode_t) mode, |
| weight_decay, |
| inv_scale.data_ptr<float>()); ) |
|
|
| AT_CUDA_CHECK(cudaGetLastError()); |
|
|
| } |
|
|
|
|
