mirror of https://github.com/hpcaitech/ColossalAI
136 lines
4.1 KiB
Plaintext
136 lines
4.1 KiB
Plaintext
#include <ATen/ATen.h>
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#include <ATen/AccumulateType.h>
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#include <ATen/cuda/CUDAContext.h>
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#include <ATen/cuda/Exceptions.h>
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// Another possibility:
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// #include <torch/all.h>
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#include <assert.h>
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// Stringstream is a big hammer, but I want to rely on operator<< for dtype.
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#include <sstream>
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#include "type_shim.h"
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#include "multi_tensor_apply.cuh"
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#define BLOCK_SIZE 512
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#define ILP 4
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template<typename T>
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__device__ __forceinline__ bool is_aligned(T* p){
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return ((uint64_t)p) % (ILP*sizeof(T)) == 0;
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}
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template<typename T>
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__device__ __forceinline__ void load_store(T* dst, T* src, int dst_offset, int src_offset){
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typedef typename std::aligned_storage<ILP*sizeof(T), ILP*alignof(T)>::type LT;
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((LT*)dst)[dst_offset] = ((LT*)src)[src_offset];
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}
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template<typename in_t, typename out_t>
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struct ScaleFunctor
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{
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__device__ __forceinline__ void operator()(
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int chunk_size,
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volatile int* noop_gmem,
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TensorListMetadata<2>& tl,
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float scale)
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{
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// I'd like this kernel to propagate infs/nans.
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// if(*noop_gmem == 1)
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// return;
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int tensor_loc = tl.block_to_tensor[blockIdx.x];
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int chunk_idx = tl.block_to_chunk[blockIdx.x];
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int n = tl.sizes[tensor_loc];
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in_t* in = (in_t*)tl.addresses[0][tensor_loc];
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in += chunk_idx*chunk_size;
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out_t* out = (out_t*)tl.addresses[1][tensor_loc];
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out += chunk_idx*chunk_size;
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n -= chunk_idx*chunk_size;
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bool finite = true;
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in_t r_in[ILP];
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out_t r_out[ILP];
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// to make things simple, we put aligned case in a different code path
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if(n % ILP == 0 && chunk_size % ILP == 0 && is_aligned(in) && is_aligned(out))
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{
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for(int i_start = threadIdx.x; i_start*ILP < n && i_start*ILP < chunk_size; i_start += blockDim.x)
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{
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// load
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load_store(r_in, in, 0 , i_start);
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#pragma unroll
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for(int ii = 0; ii < ILP; ii++)
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{
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r_out[ii] = static_cast<float>(r_in[ii]) * scale;
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finite = finite && isfinite(r_in[ii]);
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}
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// store
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load_store(out, r_out, i_start, 0);
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}
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}
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else
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{
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// Non-divergent exit condition for __syncthreads, not necessary here
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for(int i_start = 0; i_start < n && i_start < chunk_size; i_start += blockDim.x*ILP)
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{
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#pragma unroll
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for(int ii = 0; ii < ILP; ii++)
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{
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r_in[ii] = 0;
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int i = i_start + threadIdx.x + ii*blockDim.x;
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if(i < n && i < chunk_size)
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r_in[ii] = in[i];
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}
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// note for clarification to future michael:
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// From a pure memory dependency perspective, there's likely no point unrolling
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// the write loop, since writes just fire off once their LDGs arrive.
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// Put another way, the STGs are dependent on the LDGs, but not on each other.
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// There is still compute ILP benefit from unrolling the loop though.
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#pragma unroll
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for(int ii = 0; ii < ILP; ii++)
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{
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r_out[ii] = static_cast<float>(r_in[ii]) * scale;
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finite = finite && isfinite(r_in[ii]);
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}
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#pragma unroll
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for(int ii = 0; ii < ILP; ii++)
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{
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int i = i_start + threadIdx.x + ii*blockDim.x;
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if(i < n && i < chunk_size)
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out[i] = r_out[ii];
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}
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}
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}
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if(!finite)
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*noop_gmem = 1; // Blindly fire off a write. These will race but that's ok.
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}
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};
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void multi_tensor_scale_cuda(
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int chunk_size,
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at::Tensor noop_flag,
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std::vector<std::vector<at::Tensor>> tensor_lists,
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float scale)
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{
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using namespace at;
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// The output (downscaled) type is always float.
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// If build times suffer, think about where to put this dispatch,
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// and what logic should be moved out of multi_tensor_apply.
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DISPATCH_FLOAT_AND_HALF(tensor_lists[0][0].scalar_type(), 0, "multi_tensor_scale_cuda",
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DISPATCH_FLOAT_AND_HALF(tensor_lists[1][0].scalar_type(), 1, "multi_tensor_scale_cuda",
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multi_tensor_apply<2>(
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BLOCK_SIZE,
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chunk_size,
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noop_flag,
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tensor_lists,
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ScaleFunctor<scalar_t_0, scalar_t_1>(),
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scale); ))
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AT_CUDA_CHECK(cudaGetLastError());
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// AT_CUDA_CHECK(cudaDeviceSynchronize());
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} |