torch-mlir/python/npcomp/tracing/mlir_trace.py

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2020-04-27 06:50:23 +08:00
# Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
# See https://llvm.org/LICENSE.txt for license information.
# SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
import re
from typing import Iterable, Optional
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import numpy as np
from mlir import ir as _ir
from mlir.dialects import std as std_ops
from npcomp import _cext
from npcomp.dialects import basicpy as basicpy_ops
from npcomp.dialects import numpy as numpy_ops
from ..exporter import *
from ..types import *
from ..compiler.utils.mlir_utils import *
from .context import *
from .emitters import *
class ModuleBuilder:
"""Builds an MLIR module by tracing functions."""
__slots__ = [
"emitters",
"ic",
]
def __init__(self,
mlir_context: Optional[_ir.Context] = None,
emitter_registry=None):
ic = self.ic = ImportContext(mlir_context)
ic.module = _ir.Module.create(loc=ic.loc)
self.emitters = (emitter_registry
if emitter_registry else EmitterRegistry.create_default())
@property
def module(self):
return self.ic.module
def trace(self, *export_py_funcs: ExportPyFunction):
"""Traces exported py functions."""
for export_py_func in export_py_funcs:
assert isinstance(export_py_func, ExportPyFunction), (
"Expected an exported python function (from the Exporter class)")
tracer = FunctionTracer(self, export_py_func)
with tracer:
tracer.trace()
class FunctionTracer(TraceContext):
"""A trace of a single function."""
__slots__ = [
"module_builder",
"epf",
"_args_array_params",
"_f",
"_f_types",
"_ic",
"_python_args",
"_result_array_params",
"_traced_arrays",
"_external_arrays",
]
def __init__(self, module_builder: ModuleBuilder, epf: ExportPyFunction):
super().__init__(desc="[trace of %s]" % epf.__name__)
self.module_builder = module_builder
self.epf = epf
self._traced_arrays = {} # Mapping of TracedArray to current consumer value
self._external_arrays = {} # Mapping of id to (ndarray, ir.Value)
self._validate()
# Alias some parent members for convenience.
self._ic = module_builder.ic
with self._ic.context:
# Extract ArrayParams for all args and results.
self._args_array_params = [
ArrayParams.from_constraints(arg.constraints)
for arg in self.epf.sig.args
]
self._python_args = [None] * len(self._args_array_params)
self._result_array_params = ArrayParams.from_constraints(
self.epf.sig.result.constraints)
# Create the MLIR function.
self._f, self._f_types = self._create_mlir_function()
self._create_trace_roots()
@property
def entry_block(self) -> _ir.Block:
return self._f.regions[0].blocks[0]
def trace(self):
# Invoke the python function with placeholders.
# TODO: More sophisticated signature merging
# TODO: Multiple results
# TODO: Error reporting
ic = self._ic
ic.insert_end_of_block(self.entry_block)
with ic.context:
py_results = (self.epf.pyfunc(*self._python_args),)
if len(py_results) != len(self._f_types):
raise TracingError("Traced function returned != %d results: %r" % (
len(self._f_types),
py_results,
))
# Narrow all results to the declared return types.
return_operands = []
for py_result, mlir_result_type in zip(py_results, self._f_types):
mlir_result = self.get_traced_array_value(py_result)
# narrow to declared result type.
return_operands.extend(
numpy_ops.NarrowOp(mlir_result_type,
mlir_result,
loc=ic.loc,
ip=ic.ip).results)
std_ops.ReturnOp(return_operands, loc=ic.loc, ip=ic.ip)
ic.pop_ip()
def set_traced_array(self, traced_array, value):
"""Sets the current SSA value for a traced_array."""
assert isinstance(traced_array, TracedArray)
self._traced_arrays[traced_array] = value
def get_traced_array_value(self, traced_array):
if not isinstance(traced_array, TracedArray):
# Generic import of external value. For now, we just treat these as
# local consts.
return self._get_external_array_value(traced_array)
traced_value = self._traced_arrays.get(traced_array)
if traced_value is None:
raise TracingError("Unregistered traced array: %r", (traced_array,))
return traced_value
def _get_external_array_value(self, external_array):
ic = self._ic
if not isinstance(external_array, np.ndarray):
raise TracingError("Expected ndarray but got: %r" % (external_array,))
found_it = self._external_arrays.get(id(external_array))
if found_it:
return found_it[1]
# Import it.
dense_attr = _ir.DenseElementsAttr.get(external_array, context=ic.context)
const_value = std_ops.ConstantOp(dense_attr.type,
dense_attr,
loc=ic.loc,
ip=ic.ip).result
self._external_arrays[id(external_array)] = (external_array, const_value)
return const_value
def _validate(self):
if not all(
arg.type_class == TypeClass.NdArray for arg in self.epf.sig.args):
raise NotImplementedError("Non NdArray args: %r" % (self.epf.sig.args,))
if not self.epf.sig.result.type_class == TypeClass.NdArray:
raise NotImplementedError("Non NdArray result: %r" %
(self.epf.sig.result,))
def _create_mlir_function(self):
ic = self._ic
epf = self.epf
f_args = [
_ir.Type.parse(ap.mlir_tensor_type_asm)
for ap in self._args_array_params
]
f_types = [_ir.Type.parse(self._result_array_params.mlir_tensor_type_asm)]
ic.insert_end_of_block(ic.module.body)
f_type = _ir.FunctionType.get(f_args, f_types)
f, _ = ic.FuncOp(epf.__name__, f_type, create_entry_block=True)
return f, f_types
def _create_trace_roots(self):
entry_block = self.entry_block
for index, ap in enumerate(self._args_array_params):
if ap is not None:
ta = TracedArray(self)
self.set_traced_array(ta, entry_block.arguments[index])
self._python_args[index] = ta
def _resolve_input_ssa_values(self, trace_values: Iterable[TraceValue]):
"""Resolves input python values to SSA values."""
ssa_values = []
for tv in trace_values:
assert tv.type == TraceValueType.NDARRAY, (
"Unsupported TraceValueType: %r" % tv.type)
ssa_value = self.get_traced_array_value(tv.value)
ssa_values.append(ssa_value)
return ssa_values
def _resolve_result_py_values(self,
trace_value_types: Iterable[TraceValueType],
ssa_values):
"""Resolves result SSA values to runtime python values."""
assert len(trace_value_types) == len(ssa_values), (
"Mismatched emitter declared result types and results")
py_values = []
for trace_value_type, ssa_value in zip(trace_value_types, ssa_values):
assert trace_value_type == TraceValueType.NDARRAY, (
"Unsupported TraceValueType: %r" % trace_value_type)
py_value = TracedArray(self)
self.set_traced_array(py_value, ssa_value)
py_values.append(py_value)
return py_values
def _emit_invocation(self, emitter: FuncEmitter, invocation: TraceInvocation):
tv_map = emitter.map_invocation(invocation)
input_ssa_values = self._resolve_input_ssa_values(tv_map.input_trace_values)
request = EmissionRequest(input_ssa_values, ic=self._ic, extra=tv_map.extra)
result_ssa_values = emitter.emit(request)
py_values = self._resolve_result_py_values(tv_map.result_trace_value_types,
result_ssa_values)
return emitter.map_results(py_values, tv_map.extra)
def _handle_ufunc(self, ufunc, method, inputs, kwargs):
emitter = self.module_builder.emitters.lookup_ufunc(ufunc, method)
if not emitter:
return NotImplemented
invocation = TraceInvocation(inputs, kwargs, Protocol.UFUNC, method)
return self._emit_invocation(emitter, invocation)
def _handle_array_func(self, func, types, inputs, kwargs):
emitter = self.module_builder.emitters.lookup_array_func(func)
if not emitter:
return NotImplemented
invocation = TraceInvocation(inputs, kwargs, Protocol.ARRAY_FUNC)
return self._emit_invocation(emitter, invocation)
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def _emit_slice_value(self, slice_element):
ic = self._ic
if slice_element == None:
return basicpy_ops.SingletonOp(ic.none_type, loc=ic.loc, ip=ic.ip).result
elif slice_element == Ellipsis:
return basicpy_ops.SingletonOp(ic.ellipsis_type, loc=ic.loc,
ip=ic.ip).result
elif isinstance(slice_element, int):
return std_ops.ConstantOp(ic.index_type,
_ir.IntegerAttr.get(ic.index_type,
slice_element),
loc=ic.loc,
ip=ic.ip).result
elif isinstance(slice_element, slice):
return self._emit_slice_object(slice_element)
else:
# Assume array convertible.
raise NotImplementedError(
"TODO: Slicing with generic arrays not yet implemented")
def _emit_slice_object(self, slice_object: slice):
ic = self._ic
def emit_index(index):
if index is None:
return basicpy_ops.SingletonOp(ic.none_type, loc=ic.loc,
ip=ic.ip).result
else:
return std_ops.ConstantOp(ic.index_type,
_ir.IntegerAttr.get(ic.index_type,
int(index)),
loc=ic.loc,
ip=ic.ip).result
start = emit_index(slice_object.start)
stop = emit_index(slice_object.stop)
step = emit_index(slice_object.step)
result_type = _cext.slot_object_type(ic.context, "slice",
[start.type, stop.type, step.type])
return basicpy_ops.SlotObjectMakeOp(result_type, [start, stop, step],
loc=ic.loc,
ip=ic.ip).result
def _handle_array_getitem(self, array, key):
ic = self._ic
array_value = self.get_traced_array_value(array)
# Array slicing is always based on a tuple.
slice_tuple = key if isinstance(key, tuple) else (key,)
# Resolve and emit each slice element.
slice_values = [self._emit_slice_value(elt) for elt in slice_tuple]
result_value = numpy_ops.GetSliceOp(ic.unknown_array_type,
array_value,
slice_values,
loc=ic.loc,
ip=ic.ip).result
result_array = TracedArray(self)
self.set_traced_array(result_array, result_value)
return result_array
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if __name__ == "__main__":
import doctest
doctest.testmod()