293 lines
21 KiB
C
293 lines
21 KiB
C
// Copyright (c) Facebook, Inc. and its affiliates.
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//
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// This source code is licensed under the MIT license found in the
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// LICENSE file in the root directory of this source tree.
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#if BUILD_CUDA
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#include <ops.cuh>
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#endif
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#include <cpu_ops.h>
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// We cannot call templated code from C, so we wrap the template in a C compatible call here if necessary.
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// We use macro functions to expand all the different optimizers. Looks ugly, and is ugly, but its better than to
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// maintain all that boilerplate
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//===================================================================================
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// UNMANGLED CALLS
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//===================================================================================
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#if BUILD_CUDA
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void estimateQuantiles_fp32(float *A, float *code, float offset, int n){ estimateQuantiles<float>(A, code, offset, n); }
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void estimateQuantiles_fp16(half *A, float *code, float offset, int n){ estimateQuantiles<half>(A, code, offset, n); }
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#define MAKE_FUNC32(fname, oname, gtype, gbits) \
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void fname##32bit_g##gbits(gtype *g, gtype *p, \
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float* state1, float* state2, float *unorm, float max_unorm, float param_norm, \
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const float beta1, const float beta2, const float eps, const float weight_decay, \
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const int step, const float lr, float gnorm_scale, bool skip_zeros, const int n) \
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{ optimizer32bit<gtype, oname>(g, p, state1, state2, unorm, max_unorm, param_norm, beta1, beta2, eps, weight_decay, step, lr, gnorm_scale, skip_zeros, n); } \
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MAKE_FUNC32(momentum, MOMENTUM, float, 32)
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MAKE_FUNC32(momentum, MOMENTUM, half, 16)
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MAKE_FUNC32(adam, ADAM, float, 32)
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MAKE_FUNC32(adam, ADAM, half, 16)
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MAKE_FUNC32(rmsprop, RMSPROP, float, 32)
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MAKE_FUNC32(rmsprop, RMSPROP, half, 16)
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MAKE_FUNC32(adagrad, ADAGRAD, float, 32)
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MAKE_FUNC32(adagrad, ADAGRAD, half, 16)
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#define MAKE_FUNC8(fname, oname, gtype, gbits) \
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void fname##_static_8bit_g##gbits(gtype* p, gtype* g, unsigned char* state1, unsigned char* state2, \
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float *unorm, float max_unorm, float param_norm, \
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float beta1, float beta2, \
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float eps, int step, float lr, \
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float* quantiles1, float* quantiles2, \
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float* max1, float* max2, float* new_max1, float* new_max2, \
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float weight_decay, float gnorm_scale, int n) \
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{ \
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optimizerStatic8bit<gtype, oname>(g, p, state1, state2, unorm, max_unorm, param_norm, beta1, beta2, eps, step, lr, \
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quantiles1, quantiles2, max1, max2, new_max1, new_max2, weight_decay, gnorm_scale, n); \
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} \
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MAKE_FUNC8(adam, ADAM, float, 32)
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MAKE_FUNC8(adam, ADAM, half, 16)
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MAKE_FUNC8(momentum, MOMENTUM, float, 32)
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MAKE_FUNC8(momentum, MOMENTUM, half, 16)
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MAKE_FUNC8(rmsprop, RMSPROP, float, 32)
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MAKE_FUNC8(rmsprop, RMSPROP, half, 16)
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#define MAKE_BLOCKWISE8(fname, optim_name, gtype, gbits) \
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void fname##_8bit_blockwise_fp##gbits(gtype* p, gtype* g, \
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unsigned char* state1, unsigned char* state2, float beta1, float beta2, float eps, int step, float lr, \
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float* quantiles1, float* quantiles2, float* absmax1, float* absmax2, float weight_decay, const float gnorm_scale, bool skip_zeros, int n)\
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{ optimizerStatic8bitBlockwise<gtype, optim_name>(p, g, state1, state2, beta1, beta2, eps, step, lr, quantiles1, quantiles2, absmax1, absmax2, weight_decay, gnorm_scale, skip_zeros, n); }\
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MAKE_BLOCKWISE8(adam, ADAM, half, 16)
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MAKE_BLOCKWISE8(adam, ADAM, float, 32)
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MAKE_BLOCKWISE8(momentum, MOMENTUM, half, 16)
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MAKE_BLOCKWISE8(momentum, MOMENTUM, float, 32)
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MAKE_BLOCKWISE8(rmsprop, RMSPROP, half, 16)
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MAKE_BLOCKWISE8(rmsprop, RMSPROP, float, 32)
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MAKE_BLOCKWISE8(adagrad, ADAGRAD, half, 16)
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MAKE_BLOCKWISE8(adagrad, ADAGRAD, float, 32)
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void percentileClipping_g32(float * g, float *gnorm_vec, int step, const int n){ percentileClipping<float>(g, gnorm_vec, step, n); }
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void percentileClipping_g16(half * g, float *gnorm_vec, int step, const int n){ percentileClipping<half>(g, gnorm_vec, step, n); }
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void quantizeBlockwise_fp16(float * code, half *A, float *absmax, unsigned char *out, int blocksize, const int n){ quantizeBlockwise<half, 0>(code, A, absmax, out, NULL, 0, blocksize, n); }
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void quantizeBlockwise_fp32(float * code, float *A, float *absmax, unsigned char *out, int blocksize, const int n){ quantizeBlockwise<float, 0>(code, A, absmax, out, NULL, 0, blocksize, n); }
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void quantizeBlockwise_stochastic_fp16(float * code, half *A, float *absmax, unsigned char *out, float* rand, int rand_offset, const int n){ quantizeBlockwise<half, 1>(code, A, absmax, out, rand, rand_offset, 4096, n); }
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void quantizeBlockwise_stochastic_fp32(float * code, float *A, float *absmax, unsigned char *out, float* rand, int rand_offset, const int n){ quantizeBlockwise<float, 1>(code, A, absmax, out, rand, rand_offset, 4096, n); }
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void dequantizeBlockwise_fp16(float *code, unsigned char *A, float *absmax, half *out, int blocksize, const int n){ dequantizeBlockwise<half>(code, A, absmax, out, blocksize, n); } \
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void dequantizeBlockwise_fp32(float *code, unsigned char *A, float *absmax, float *out, int blocksize, const int n){ dequantizeBlockwise<float>(code, A, absmax, out, blocksize, n); }
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#define MAKE_FUNC_TRANSFORM(fbits, fsrc, ftrgt, ftranspose, dtype, src, target, transpose, bits) \
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void transform_##fbits##_##fsrc##_to_##ftrgt##_##ftranspose(cublasLtHandle_t ltHandle, dtype *A, dtype *out, int dim1, int dim2) \
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{ \
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transform<dtype, src, target, transpose, bits>(ltHandle, A, out, dim1, dim2); \
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} \
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MAKE_FUNC_TRANSFORM(8, row, col, n, int8_t, ROW, COL, false, 8);
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MAKE_FUNC_TRANSFORM(8, row, row, n, int8_t, ROW, ROW, false, 8);
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MAKE_FUNC_TRANSFORM(8, row, col32, n, int8_t, ROW, COL32, false, 8);
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MAKE_FUNC_TRANSFORM(32, row, col32, n, int32_t, ROW, COL32, false, 32);
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MAKE_FUNC_TRANSFORM(8, row, col_turing, n, int8_t, ROW, COL_TURING, false, 8);
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MAKE_FUNC_TRANSFORM(8, row, col_ampere, n, int8_t, ROW, COL_AMPERE, false, 8);
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MAKE_FUNC_TRANSFORM(8, col32, row, n, int8_t, COL32, ROW, false, 8);
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MAKE_FUNC_TRANSFORM(32, col32, row, n, int32_t, COL32, ROW, false, 32);
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void transform_row2col32(char * A, char *out, int rows, int cols){ transformRowToFormat<COL32, 0>(A, out, rows, cols); }
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void transform_row2col32T(char * A, char *out, int rows, int cols){ transformRowToFormat<COL32, 1>(A, out, rows, cols); }
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void transform_row2turing(char * A, char *out, int rows, int cols){ transformRowToFormat<COL_TURING, 0>(A, out, rows, cols); }
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void transform_row2turingT(char * A, char *out, int rows, int cols){ transformRowToFormat<COL_TURING, 1>(A, out, rows, cols); }
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void transform_row2ampere(char * A, char *out, int rows, int cols){ transformRowToFormat<COL_AMPERE, 0>(A, out, rows, cols); }
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void transform_row2ampereT(char * A, char *out, int rows, int cols){ transformRowToFormat<COL_AMPERE, 1>(A, out, rows, cols); }
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void extractOutliers_turing(char * A, int *idx, char *out, int idx_size, int rows, int cols){ extractOutliers<COL_TURING>(A, idx, out, idx_size, rows, cols); }
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void extractOutliers_ampere(char * A, int *idx, char *out, int idx_size, int rows, int cols){ extractOutliers<COL_AMPERE>(A, idx, out, idx_size, rows, cols); }
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int igemmlt_turing_32(cublasLtHandle_t ltHandle, int m, int n, int k, const int8_t *A, const int8_t *B, void *C, float *row_scale, int lda, int ldb, int ldc)
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{ return igemmlt<COL_TURING, 32, 0>(ltHandle, m, n, k, A, B, C, row_scale, lda, ldb, ldc); }
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int igemmlt_turing_8(cublasLtHandle_t ltHandle, int m, int n, int k, const int8_t *A, const int8_t *B, void *C, float *row_scale, int lda, int ldb, int ldc)
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{ return igemmlt<COL_TURING, 8, 0>(ltHandle, m, n, k, A, B, C, row_scale, lda, ldb, ldc); }
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int igemmlt_turing_8_rowscale(cublasLtHandle_t ltHandle, int m, int n, int k, const int8_t *A, const int8_t *B, void *C, float *row_scale, int lda, int ldb, int ldc)
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{ return igemmlt<COL_TURING, 8, 1>(ltHandle, m, n, k, A, B, C, row_scale, lda, ldb, ldc); }
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int igemmlt_ampere_32(cublasLtHandle_t ltHandle, int m, int n, int k, const int8_t *A, const int8_t *B, void *C, float *row_scale, int lda, int ldb, int ldc)
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{ return igemmlt<COL_AMPERE, 32, 0>(ltHandle, m, n, k, A, B, C, row_scale, lda, ldb, ldc); }
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int igemmlt_ampere_8(cublasLtHandle_t ltHandle, int m, int n, int k, const int8_t *A, const int8_t *B, void *C, float *row_scale, int lda, int ldb, int ldc)
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{ return igemmlt<COL_AMPERE, 8, 0>(ltHandle, m, n, k, A, B, C, row_scale, lda, ldb, ldc); }
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int igemmlt_ampere_8_rowscale(cublasLtHandle_t ltHandle, int m, int n, int k, const int8_t *A, const int8_t *B, void *C, float *row_scale, int lda, int ldb, int ldc)
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{ return igemmlt<COL_AMPERE, 8, 1>(ltHandle, m, n, k, A, B, C, row_scale, lda, ldb, ldc); }
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void spmm_coo_very_sparse_naive_fp16(int *max_count, int *max_idx, int *offset_rowidx, int *rowidx, int *colidx, half *values, half *B, half *out, float *dequant_stats, int nnz_rows, int nnz, int rowsA, int rowsB, int colsB)
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{ spmm_coo_very_sparse_naive<half, 16>(max_count, max_idx, offset_rowidx, rowidx, colidx, values, B, out, dequant_stats, nnz_rows, nnz, rowsA, rowsB, colsB); }
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void spmm_coo_very_sparse_naive_int8(int *max_count, int *max_idx, int *offset_rowidx, int *rowidx, int *colidx, half *values, signed char *B, half *out, float *dequant_stats, int nnz_rows, int nnz, int rowsA, int rowsB, int colsB)
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{ spmm_coo_very_sparse_naive<signed char, 8>(max_count, max_idx, offset_rowidx, rowidx, colidx, values, B, out, dequant_stats, nnz_rows, nnz, rowsA, rowsB, colsB); }
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#endif
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extern "C"
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{
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#if BUILD_CUDA
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void cestimate_quantiles_fp32(float *A, float *code, float offset, int n){ estimateQuantiles_fp32(A, code, offset, n); }
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void cestimate_quantiles_fp16(half *A, float *code, float offset, int n){ estimateQuantiles_fp16(A, code, offset, n); }
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void cquantize(float *code, float *A, unsigned char *out, int n){ quantize(code, A, out, n); }
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void cdequantize(float *code, unsigned char *A, float *out, int n){ dequantize(code, A, out, n); }
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void cquantize_blockwise_fp16(float * code, half *A, float *absmax, unsigned char *out, int blocksize, const int n){ quantizeBlockwise_fp16(code, A, absmax, out, blocksize, n); }
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void cquantize_blockwise_fp32(float * code, float *A, float *absmax, unsigned char *out, int blocksize, const int n){ quantizeBlockwise_fp32(code, A, absmax, out, blocksize, n); }
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void cquantize_blockwise_stochastic_fp16(float * code, half *A, float *absmax, unsigned char *out, float *rand, int rand_offset, const int n){ quantizeBlockwise_stochastic_fp16(code, A, absmax, out, rand, rand_offset, n); }
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void cquantize_blockwise_stochastic_fp32(float * code, float *A, float *absmax, unsigned char *out, float *rand, int rand_offset, const int n){ quantizeBlockwise_stochastic_fp32(code, A, absmax, out, rand, rand_offset, n); }
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void cdequantize_blockwise_fp16(float *code, unsigned char *A, float *absmax, half *out, int blocksize, const int n){ dequantizeBlockwise_fp16(code, A, absmax, out, blocksize, n); }
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void cdequantize_blockwise_fp32(float *code, unsigned char *A, float *absmax, float *out, int blocksize, const int n){ dequantizeBlockwise_fp32(code, A, absmax, out, blocksize, n); }
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#define MAKE_CFUNC32(name, gtype, gbits) \
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void c##name##32bit_g##gbits(gtype *g, gtype *p, \
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float* state1, float* state2, float *unorm, float max_unorm, float param_norm, \
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const float beta1, const float beta2, const float eps, const float weight_decay, \
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const int step, const float lr, const float gnorm_scale, bool skip_zeros, const int n) \
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{ name##32bit_g##gbits(g, p, state1, state2, unorm, max_unorm, param_norm, beta1, beta2, eps, weight_decay, step, lr, gnorm_scale, skip_zeros, n); } \
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MAKE_CFUNC32(adam, float, 32)
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MAKE_CFUNC32(adam, half, 16)
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MAKE_CFUNC32(momentum, float, 32)
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MAKE_CFUNC32(momentum, half, 16)
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MAKE_CFUNC32(rmsprop, float, 32)
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MAKE_CFUNC32(rmsprop, half, 16)
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MAKE_CFUNC32(adagrad, float, 32)
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MAKE_CFUNC32(adagrad, half, 16)
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#define MAKE_CFUNC8(name, gtype, gbits) \
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void c##name##_static_8bit_g##gbits(gtype* p, gtype* g, unsigned char* state1, unsigned char* state2, \
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float *unorm, float max_unorm, float param_norm, \
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float beta1, float beta2, \
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float eps, int step, float lr, \
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float* quantiles1, float* quantiles2, \
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float* max1, float* max2, float* new_max1, float* new_max2, \
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float weight_decay, float gnorm_scale, int n) \
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{ \
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name##_static_8bit_g##gbits(g, p, state1, state2, unorm, max_unorm, param_norm, beta1, beta2, eps, step, lr, \
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quantiles1, quantiles2, max1, max2, new_max1, new_max2, weight_decay, gnorm_scale, n); \
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} \
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MAKE_CFUNC8(adam, float, 32)
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MAKE_CFUNC8(adam, half, 16)
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MAKE_CFUNC8(momentum, float, 32)
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MAKE_CFUNC8(momentum, half, 16)
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MAKE_CFUNC8(rmsprop, float, 32)
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MAKE_CFUNC8(rmsprop, half, 16)
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#define MAKE_CBLOCKWISE8(fname, optim_name, gtype, gbits) \
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void c##fname##_8bit_blockwise_fp##gbits(gtype* p, gtype* g, \
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unsigned char* state1, unsigned char* state2, float beta1, float beta2, float eps, int step, float lr, \
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float* quantiles1, float* quantiles2, float* absmax1, float* absmax2, float weight_decay, const float gnorm_scale, bool skip_zeros, int n) \
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{ fname##_8bit_blockwise_fp##gbits(p, g, state1, state2, beta1, beta2, eps, step, lr, quantiles1, quantiles2, absmax1, absmax2, weight_decay, gnorm_scale, skip_zeros, n); } \
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MAKE_CBLOCKWISE8(adam, ADAM, half, 16)
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MAKE_CBLOCKWISE8(adam, ADAM, float, 32)
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MAKE_CBLOCKWISE8(momentum, MOMENTUM, half, 16)
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MAKE_CBLOCKWISE8(momentum, MOMENTUM, float, 32)
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MAKE_CBLOCKWISE8(rmsprop, RMSPROP, half, 16)
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MAKE_CBLOCKWISE8(rmsprop, RMSPROP, float, 32)
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MAKE_CBLOCKWISE8(adagrad, ADAGRAD, half, 16)
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MAKE_CBLOCKWISE8(adagrad, ADAGRAD, float, 32)
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void cpercentile_clipping_g32(float * g, float *gnorm_vec, int step, const int n){ percentileClipping_g32(g, gnorm_vec, step, n); }
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void cpercentile_clipping_g16(half * g, float *gnorm_vec, int step, const int n){ percentileClipping_g16(g, gnorm_vec, step, n); }
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void chistogram_scatter_add_2d(float* histogram, int *index1, int *index2, float *src, int maxidx1, int n){ histogramScatterAdd2D(histogram, index1, index2, src, maxidx1, n); }
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void cigemm(Context *context, bool transposeA, bool transposeB, int m, int n, int k, void *A, void *B, void *C, int lda, int ldb, int ldc)
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{ gemmex(context, transposeA, transposeB, m, n, k, A, B, C, lda, ldb, ldc); }
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void cbatched_igemm(Context *context, bool transposeA, bool transposeB, int m, int n, int k, void *A, void *B, void *C, int lda, int ldb, int ldc,
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long strideA, long strideB, long strideC, int batchCount)
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{ strided_gemmex(context, transposeA, transposeB, m, n, k, A, B, C, lda, ldb, ldc, strideA, strideB, strideC, batchCount); }
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Context *get_context(){ return new Context(); }
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ContextCusparse *get_cusparse(){ return new ContextCusparse(); }
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int cigemmlt_turing_32(Context *context, int m, int n, int k, const int8_t *A, const int8_t *B, void *C, float *row_scale, int lda, int ldb, int ldc)
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{ return igemmlt_turing_32((cublasLtHandle_t) context->m_handle, m, n, k, A, B, C, row_scale, lda, ldb, ldc); }
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//{ (cublasLtHandle_t)context->m_handle; return 0; }
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//{ return 0; }//igemmlt_turing_32((cublasLtHandle_t) context->m_handle, m, n, k, A, B, C, row_scale, lda, ldb, ldc); }
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int cigemmlt_turing_8(Context *context, int m, int n, int k, const int8_t *A, const int8_t *B, void *C, float *row_scale, int lda, int ldb, int ldc)
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{ return igemmlt_turing_8((cublasLtHandle_t) context->m_handle, m, n, k, A, B, C, row_scale, lda, ldb, ldc); }
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int cigemmlt_turing_8_rowscale(Context *context, int m, int n, int k, const int8_t *A, const int8_t *B, void *C, float *row_scale, int lda, int ldb, int ldc)
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{ return igemmlt_turing_8_rowscale((cublasLtHandle_t) context->m_handle, m, n, k, A, B, C, row_scale, lda, ldb, ldc); }
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int cigemmlt_ampere_32(Context *context, int m, int n, int k, const int8_t *A, const int8_t *B, void *C, float *row_scale, int lda, int ldb, int ldc)
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{ return igemmlt_ampere_32((cublasLtHandle_t) context->m_handle, m, n, k, A, B, C, row_scale, lda, ldb, ldc); }
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int cigemmlt_ampere_8_rowscale(Context *context, int m, int n, int k, const int8_t *A, const int8_t *B, void *C, float *row_scale, int lda, int ldb, int ldc)
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{ return igemmlt_ampere_8_rowscale((cublasLtHandle_t) context->m_handle, m, n, k, A, B, C, row_scale, lda, ldb, ldc); }
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int cigemmlt_ampere_8(Context *context, int m, int n, int k, const int8_t *A, const int8_t *B, void *C, float *row_scale, int lda, int ldb, int ldc)
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{ return igemmlt_ampere_8((cublasLtHandle_t) context->m_handle, m, n, k, A, B, C, row_scale, lda, ldb, ldc); }
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#define MAKE_FUNC_CTRANSFORM(fbits, fsrc, ftrgt, ftranspose, dtype, src, target, transpose, bits) \
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void ctransform_##fbits##_##fsrc##_to_##ftrgt##_##ftranspose(Context *context, dtype *A, dtype *out, int dim1, int dim2) \
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{ \
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transform_##fbits##_##fsrc##_to_##ftrgt##_##ftranspose((cublasLtHandle_t) context->m_handle, A, out, dim1, dim2); \
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} \
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MAKE_FUNC_CTRANSFORM(8, row, col, n, int8_t, ROW, COL, false, 8)
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MAKE_FUNC_CTRANSFORM(8, row, row, n, int8_t, ROW, ROW, false, 8)
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MAKE_FUNC_CTRANSFORM(8, row, col32, n, int8_t, ROW, COL32, false, 8)
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MAKE_FUNC_CTRANSFORM(32, row, col32, n, int32_t, ROW, COL32, false, 32)
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MAKE_FUNC_CTRANSFORM(8, row, col_turing, n, int8_t, ROW, COL_TURING, false, 8)
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MAKE_FUNC_CTRANSFORM(8, row, col_ampere, n, int8_t, ROW, COL_AMPERE, false, 8)
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MAKE_FUNC_CTRANSFORM(8, col32, row, n, int8_t, COL32, ROW, false, 8)
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MAKE_FUNC_CTRANSFORM(32, col32, row, n, int32_t, COL32, ROW, false, 32)
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void cdequant_mm_int32_fp16(int *A, float *rowStats, float *colStats, half *out, float* newRowStats, float* newcolStats, half* bias, int numRows, int numCols)
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{ dequant_mm_int32_fp16(A, rowStats, colStats, out, newRowStats, newcolStats, bias, numRows, numCols); }
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void cget_col_row_stats(half * A, float *rowStats, float *colStats, int *nnz_count_row, float nnz_threshold, int rows, int cols)
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{ getColRowStats(A, rowStats, colStats, nnz_count_row, nnz_threshold, rows, cols); }
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void cdouble_rowcol_quant(half * A, float *rowStats, float *colStats, char *out_col_normed, char *out_row_normed, int *rowidx, int *colidx, half *val, int *nnz_row_ptr, float threshold, int rows, int cols)
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{ doubleRowColQuant(A, rowStats, colStats, out_col_normed, out_row_normed, rowidx, colidx, val, nnz_row_ptr, threshold, rows, cols); }
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void ctransform_row2col32(char * A, char *out, int rows, int cols)
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{ transform_row2col32(A, out, rows, cols); }
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void ctransform_row2col32T(char * A, char *out, int rows, int cols)
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{ transform_row2col32T(A, out, rows, cols); }
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void ctransform_row2turing(char * A, char *out, int rows, int cols)
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{ transform_row2turing(A, out, rows, cols); }
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void ctransform_row2turingT(char * A, char *out, int rows, int cols)
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{ transform_row2turingT(A, out, rows, cols); }
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void ctransform_row2ampere(char * A, char *out, int rows, int cols)
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{ transform_row2ampere(A, out, rows, cols); }
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void ctransform_row2ampereT(char * A, char *out, int rows, int cols)
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{ transform_row2ampereT(A, out, rows, cols); }
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void cspmm_coo(ContextCusparse *context, int *A_rowidx, int *A_colidx, half *A_vals, int A_nnz, int A_rows, int A_cols, int B_cols, int ldb, half *B, int ldc, half* C, bool transposed_B)
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{ spmm_coo((cusparseHandle_t) context->m_handle, A_rowidx, A_colidx, A_vals, A_nnz, A_rows, A_cols, B_cols, ldb, B, ldc, C, transposed_B); }
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void cspmm_coo_very_sparse_naive_fp16(int *max_count, int *max_idx, int *offset_rowidx, int *rowidx, int *colidx, half *values, half *B, half *out, float *dequant_stats, int nnz_rows, int nnz, int rowsA, int rowsB, int colsB)
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{ spmm_coo_very_sparse_naive_fp16(max_count, max_idx, offset_rowidx, rowidx, colidx, values, B, out, dequant_stats, nnz_rows, nnz, rowsA, rowsB, colsB); }
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void cspmm_coo_very_sparse_naive_int8(int *max_count, int *max_idx, int *offset_rowidx, int *rowidx, int *colidx, half *values, signed char *B, half *out, float *dequant_stats, int nnz_rows, int nnz, int rowsA, int rowsB, int colsB)
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{ spmm_coo_very_sparse_naive_int8(max_count, max_idx, offset_rowidx, rowidx, colidx, values, B, out, dequant_stats, nnz_rows, nnz, rowsA, rowsB, colsB); }
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void cextractOutliers_turing(char * A, int *idx, char *out, int idx_size, int rows, int cols){ extractOutliers_turing(A, idx, out, idx_size, rows, cols); }
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void cextractOutliers_ampere(char * A, int *idx, char *out, int idx_size, int rows, int cols){ extractOutliers_ampere(A, idx, out, idx_size, rows, cols); }
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#endif
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void cquantize_blockwise_cpu_fp32(float *code, float *A, float *absmax, unsigned char *out, long long blocksize, long long n){ quantize_cpu(code, A, absmax, out, blocksize, n); }
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void cdequantize_blockwise_cpu_fp32(float *code, unsigned char *A, float *absmax, float *out, long long blocksize, long long n){ dequantize_cpu(code, A, absmax, out, blocksize, n); }
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}
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