ampere_research/pytorch/spmv.py

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from data_stat import Stat, Format, MatrixType
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import torch, scipy
import numpy as np
import argparse
import time
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import json
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import sys, os
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device = 'cpu'
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parser = argparse.ArgumentParser()
parser.add_argument('matrix_type', type=str,
choices=[t.name.lower() for t in MatrixType],
help='the type of matrix')
parser.add_argument('format', type=str,
choices=[fmt.name.lower() for fmt in Format],
help='the sparse format to use')
parser.add_argument('iterations', type=int, help='the number of iterations of multiplication to perform')
parser.add_argument('-m', '--matrix_file', type=str,
help='the input matrix (.mtx) file')
parser.add_argument('-ss', '--synthetic_size', type=int,
help='the synthetic matrix parameters size (rows)')
parser.add_argument('-sd', '--synthetic_density', type=float,
help='the synthetic matrix density')
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parser.add_argument('-c', '--cores', type=int,
help='the number of cores to use')
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args = parser.parse_args()
args.matrix_type = MatrixType[args.matrix_type.upper()]
args.format = Format[args.format.upper()]
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if args.cores is not None:
torch.set_num_threads(args.cores)
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if args.matrix_type == MatrixType.SUITESPARSE:
if args.matrix_file is None:
exit("Matrix file not specified!")
matrix = scipy.io.mmread(args.matrix_file)
matrix = torch.sparse_coo_tensor(
np.vstack((matrix.row, matrix.col)),
matrix.data, matrix.shape,
device=device, dtype=torch.float32)
elif args.matrix_type == MatrixType.SYNTHETIC:
if args.synthetic_size is None and args.synthetic_density is None:
exit("Synthetic matrix parameters not specified!")
nnz = int((args.synthetic_size ** 2) * args.synthetic_density)
row_indices = torch.randint(0, args.synthetic_size, (nnz,))
col_indices = torch.randint(0, args.synthetic_size, (nnz,))
indices = torch.stack([row_indices, col_indices])
values = torch.randn(nnz)
matrix = torch.sparse_coo_tensor(
indices, values,
size=(args.synthetic_size, args.synthetic_size),
device=device, dtype=torch.float32)
else:
exit("Unrecognized matrix type!")
if args.format == Format.CSR:
matrix = matrix.to_sparse_csr().type(torch.float32)
elif args.format == Format.COO:
pass
else:
exit("Unrecognized format!")
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vector = torch.rand(matrix.shape[1], device=device)
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print(matrix, file=sys.stderr)
print(vector, file=sys.stderr)
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start = time.time()
for i in range(0, args.iterations):
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torch.mv(matrix, vector)
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#torch.sparse.mm(matrix, vector.unsqueeze(-1)).squeeze(-1)
#print(i)
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end = time.time()
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result = dict()
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result[Stat.MATRIX_TYPE.name] = args.matrix_type.value
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print(f"Matrix Type: {result[Stat.MATRIX_TYPE.name]}", file=sys.stderr)
if args.matrix_type == MatrixType.SUITESPARSE:
result[Stat.MATRIX_FILE.name] = os.path.splitext(os.path.basename(args.matrix_file))[0]
print(f"Matrix: {result[Stat.MATRIX_FILE.name]}", file=sys.stderr)
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elif args.matrix_type == MatrixType.SYNTHETIC:
result[Stat.MATRIX_DENSITY_GROUP.name] = args.synthetic_density
result[Stat.MATRIX_FORMAT.name] = args.format.value
print(f"Matrix: {result[Stat.MATRIX_FORMAT.name]}", file=sys.stderr)
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result[Stat.MATRIX_SHAPE.name] = matrix.shape
print(f"Shape: {result[Stat.MATRIX_SHAPE.name]}", file=sys.stderr)
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result[Stat.MATRIX_ROWS.name] = matrix.shape[0]
print(f"Rows: {result[Stat.MATRIX_ROWS.name]}", file=sys.stderr)
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result[Stat.MATRIX_SIZE.name] = matrix.shape[0] * matrix.shape[1]
print(f"Size: {result[Stat.MATRIX_SIZE.name]}", file=sys.stderr)
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result[Stat.MATRIX_NNZ.name] = matrix.values().shape[0]
print(f"NNZ: {result[Stat.MATRIX_NNZ.name]}", file=sys.stderr)
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result[Stat.MATRIX_DENSITY.name] = matrix.values().shape[0] / (matrix.shape[0] * matrix.shape[1])
print(f"Density: {result[Stat.MATRIX_DENSITY.name]}", file=sys.stderr)
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result[Stat.TIME_S.name] = end - start
print(f"Time: {result[Stat.TIME_S.name]} seconds", file=sys.stderr)
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print(json.dumps(result))