9048ea28da
This reverts commit 5561e17411
The logic was moved from cmake into lit fixing the issue that lead to the revert and potentially others with multi-config cmake generators
Differential Revision: https://reviews.llvm.org/D143925
151 lines
5.1 KiB
Python
151 lines
5.1 KiB
Python
# RUN: env SUPPORT_LIB=%mlir_c_runner_utils \
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# RUN: %PYTHON %s | FileCheck %s
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import ctypes
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import numpy as np
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import os
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import sys
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from mlir import ir
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from mlir import runtime as rt
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from mlir.dialects import sparse_tensor as st
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from mlir.dialects import builtin
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from mlir.dialects import func
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from mlir.dialects.linalg.opdsl import lang as dsl
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_SCRIPT_PATH = os.path.dirname(os.path.abspath(__file__))
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sys.path.append(_SCRIPT_PATH)
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from tools import sparse_compiler
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@dsl.linalg_structured_op
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def matmul_dsl(
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A=dsl.TensorDef(dsl.T, dsl.S.M, dsl.S.K),
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B=dsl.TensorDef(dsl.T, dsl.S.K, dsl.S.N),
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C=dsl.TensorDef(dsl.T, dsl.S.M, dsl.S.N, output=True)):
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C[dsl.D.m, dsl.D.n] += A[dsl.D.m, dsl.D.k] * B[dsl.D.k, dsl.D.n]
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def build_SpMM(attr: st.EncodingAttr):
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"""Build SpMM kernel.
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This method generates a linalg op with for matrix multiplication using
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just the Python API. Effectively, a generic linalg op is constructed
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that computes C(i,j) += A(i,k) * B(k,j) for annotated matrix A.
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"""
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module = ir.Module.create()
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f64 = ir.F64Type.get()
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a = ir.RankedTensorType.get([3, 4], f64, attr)
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b = ir.RankedTensorType.get([4, 2], f64)
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c = ir.RankedTensorType.get([3, 2], f64)
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arguments = [a, b, c]
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with ir.InsertionPoint(module.body):
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@func.FuncOp.from_py_func(*arguments)
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def spMxM(*args):
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return matmul_dsl(args[0], args[1], outs=[args[2]])
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return module
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def boilerplate(attr: st.EncodingAttr):
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"""Returns boilerplate main method.
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This method sets up a boilerplate main method that takes three tensors
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(a, b, c), converts the first tensor a into s sparse tensor, and then
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calls the sparse kernel for matrix multiplication. For convenience,
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this part is purely done as string input.
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"""
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return f"""
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func.func @main(%ad: tensor<3x4xf64>, %b: tensor<4x2xf64>, %c: tensor<3x2xf64>) -> tensor<3x2xf64>
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attributes {{ llvm.emit_c_interface }} {{
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%a = sparse_tensor.convert %ad : tensor<3x4xf64> to tensor<3x4xf64, {attr}>
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%0 = call @spMxM(%a, %b, %c) : (tensor<3x4xf64, {attr}>,
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tensor<4x2xf64>,
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tensor<3x2xf64>) -> tensor<3x2xf64>
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return %0 : tensor<3x2xf64>
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}}
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"""
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def build_compile_and_run_SpMM(attr: st.EncodingAttr, compiler):
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# Build.
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module = build_SpMM(attr)
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func = str(module.operation.regions[0].blocks[0].operations[0].operation)
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module = ir.Module.parse(func + boilerplate(attr))
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# Compile.
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engine = compiler.compile_and_jit(module)
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# Set up numpy input and buffer for output.
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a = np.array(
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[[1.1, 0.0, 0.0, 1.4], [0.0, 0.0, 0.0, 0.0], [0.0, 0.0, 3.3, 0.0]],
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np.float64)
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b = np.array([[1.0, 2.0], [4.0, 3.0], [5.0, 6.0], [8.0, 7.0]], np.float64)
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c = np.zeros((3, 2), np.float64)
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mem_a = ctypes.pointer(ctypes.pointer(rt.get_ranked_memref_descriptor(a)))
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mem_b = ctypes.pointer(ctypes.pointer(rt.get_ranked_memref_descriptor(b)))
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mem_c = ctypes.pointer(ctypes.pointer(rt.get_ranked_memref_descriptor(c)))
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# Allocate a MemRefDescriptor to receive the output tensor.
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# The buffer itself is allocated inside the MLIR code generation.
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ref_out = rt.make_nd_memref_descriptor(2, ctypes.c_double)()
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mem_out = ctypes.pointer(ctypes.pointer(ref_out))
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# Invoke the kernel and get numpy output.
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# Built-in bufferization uses in-out buffers.
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# TODO: replace with inplace comprehensive bufferization.
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engine.invoke('main', mem_out, mem_a, mem_b, mem_c)
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# Sanity check on computed result.
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expected = np.matmul(a, b);
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c = rt.ranked_memref_to_numpy(mem_out[0])
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if np.allclose(c, expected):
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pass
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else:
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quit(f'FAILURE')
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def main():
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support_lib = os.getenv('SUPPORT_LIB')
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assert support_lib is not None, 'SUPPORT_LIB is undefined'
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if not os.path.exists(support_lib):
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raise FileNotFoundError(errno.ENOENT, os.strerror(errno.ENOENT), support_lib)
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# CHECK-LABEL: TEST: testSpMM
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print('\nTEST: testSpMM')
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with ir.Context() as ctx, ir.Location.unknown():
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count = 0
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# Loop over various ways to compile and annotate the SpMM kernel with
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# a *single* sparse tensor. Note that we deliberate do not exhaustively
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# search the full state space to reduce runtime of the test. It is
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# straightforward to adapt the code below to explore more combinations.
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vl = 1
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e = False
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opt = (f'parallelization-strategy=none')
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levels = [[st.DimLevelType.dense, st.DimLevelType.dense],
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[st.DimLevelType.dense, st.DimLevelType.compressed],
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[st.DimLevelType.compressed, st.DimLevelType.dense],
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[st.DimLevelType.compressed, st.DimLevelType.compressed]]
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orderings = [
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ir.AffineMap.get_permutation([0, 1]),
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ir.AffineMap.get_permutation([1, 0])
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]
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bitwidths = [0]
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compiler = sparse_compiler.SparseCompiler(
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options=opt, opt_level=0, shared_libs=[support_lib])
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for level in levels:
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for ordering in orderings:
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for pwidth in bitwidths:
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for iwidth in bitwidths:
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attr = st.EncodingAttr.get(level, ordering, None, pwidth, iwidth)
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build_compile_and_run_SpMM(attr, compiler)
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count = count + 1
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# CHECK: Passed 8 tests
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print('Passed ', count, 'tests')
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if __name__ == '__main__':
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main()
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