forked from OSchip/llvm-project
108 lines
4.2 KiB
Python
108 lines
4.2 KiB
Python
"""Common utilities that are useful for all the benchmarks."""
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import numpy as np
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import mlir.all_passes_registration
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from mlir import ir
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from mlir.dialects import arith
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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 import memref
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from mlir.dialects import scf
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from mlir.passmanager import PassManager
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def setup_passes(mlir_module):
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"""Setup pass pipeline parameters for benchmark functions.
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"""
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opt = (
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"parallelization-strategy=0"
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" vectorization-strategy=0 vl=1 enable-simd-index32=False"
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)
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pipeline = f"sparse-compiler{{{opt}}}"
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PassManager.parse(pipeline).run(mlir_module)
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def create_sparse_np_tensor(dimensions, number_of_elements):
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"""Constructs a numpy tensor of dimensions `dimensions` that has only a
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specific number of nonzero elements, specified by the `number_of_elements`
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argument.
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"""
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tensor = np.zeros(dimensions, np.float64)
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tensor_indices_list = [
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[np.random.randint(0, dimension) for dimension in dimensions]
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for _ in range(number_of_elements)
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]
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for tensor_indices in tensor_indices_list:
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current_tensor = tensor
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for tensor_index in tensor_indices[:-1]:
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current_tensor = current_tensor[tensor_index]
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current_tensor[tensor_indices[-1]] = np.random.uniform(1, 100)
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return tensor
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def get_kernel_func_from_module(module: ir.Module) -> func.FuncOp:
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"""Takes an mlir module object and extracts the function object out of it.
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This function only works for a module with one region, one block, and one
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operation.
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"""
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assert len(module.operation.regions) == 1, \
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"Expected kernel module to have only one region"
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assert len(module.operation.regions[0].blocks) == 1, \
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"Expected kernel module to have only one block"
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assert len(module.operation.regions[0].blocks[0].operations) == 1, \
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"Expected kernel module to have only one operation"
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return module.operation.regions[0].blocks[0].operations[0]
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def emit_timer_func() -> func.FuncOp:
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"""Returns the declaration of nano_time function. If nano_time function is
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used, the `MLIR_RUNNER_UTILS` and `MLIR_C_RUNNER_UTILS` must be included.
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"""
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i64_type = ir.IntegerType.get_signless(64)
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nano_time = func.FuncOp(
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"nano_time", ([], [i64_type]), visibility="private")
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nano_time.attributes["llvm.emit_c_interface"] = ir.UnitAttr.get()
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return nano_time
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def emit_benchmark_wrapped_main_func(func, timer_func):
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"""Takes a function and a timer function, both represented as FuncOp
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objects, and returns a new function. This new function wraps the call to
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the original function between calls to the timer_func and this wrapping
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in turn is executed inside a loop. The loop is executed
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len(func.type.results) times. This function can be used to create a
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"time measuring" variant of a function.
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"""
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i64_type = ir.IntegerType.get_signless(64)
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memref_of_i64_type = ir.MemRefType.get([-1], i64_type)
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wrapped_func = func.FuncOp(
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# Same signature and an extra buffer of indices to save timings.
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"main",
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(func.arguments.types + [memref_of_i64_type], func.type.results),
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visibility="public"
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)
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wrapped_func.attributes["llvm.emit_c_interface"] = ir.UnitAttr.get()
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num_results = len(func.type.results)
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with ir.InsertionPoint(wrapped_func.add_entry_block()):
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timer_buffer = wrapped_func.arguments[-1]
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zero = arith.ConstantOp.create_index(0)
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n_iterations = memref.DimOp(ir.IndexType.get(), timer_buffer, zero)
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one = arith.ConstantOp.create_index(1)
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iter_args = list(wrapped_func.arguments[-num_results - 1:-1])
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loop = scf.ForOp(zero, n_iterations, one, iter_args)
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with ir.InsertionPoint(loop.body):
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start = func.CallOp(timer_func, [])
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call = func.CallOp(
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func,
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wrapped_func.arguments[:-num_results - 1] + loop.inner_iter_args
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)
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end = func.CallOp(timer_func, [])
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time_taken = arith.SubIOp(end, start)
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memref.StoreOp(time_taken, timer_buffer, [loop.induction_variable])
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scf.YieldOp(list(call.results))
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func.ReturnOp(loop)
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return wrapped_func
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