Source code for funsor.optimizer

import collections

from multipledispatch.variadic import Variadic
from opt_einsum.paths import greedy

import funsor.interpreter as interpreter
from funsor.cnf import Contraction, nullop
from funsor.ops import DISTRIBUTIVE_OPS, AssociativeOp
from funsor.terms import Funsor, eager, lazy, normalize


[docs]@interpreter.dispatched_interpretation def unfold(cls, *args): result = unfold.dispatch(cls, *args)(*args) if result is None: result = normalize.dispatch(cls, *args)(*args) if result is None: result = lazy(cls, *args) return result
[docs]@unfold.register(Contraction, AssociativeOp, AssociativeOp, frozenset, tuple) def unfold_contraction_generic_tuple(red_op, bin_op, reduced_vars, terms): for i, v in enumerate(terms): if not isinstance(v, Contraction): continue if v.red_op is nullop and (v.bin_op, bin_op) in DISTRIBUTIVE_OPS: # a * e * (b + c + d) -> (a * e * b) + (a * e * c) + (a * e * d) new_terms = tuple( Contraction(v.red_op, bin_op, v.reduced_vars, *(terms[:i] + (vt,) + terms[i+1:])) for vt in v.terms) return Contraction(red_op, v.bin_op, reduced_vars, *new_terms) if red_op in (v.red_op, nullop) and (v.red_op, bin_op) in DISTRIBUTIVE_OPS: new_terms = terms[:i] + (Contraction(v.red_op, v.bin_op, frozenset(), *v.terms),) + terms[i+1:] return Contraction(v.red_op, bin_op, v.reduced_vars, *new_terms).reduce(red_op, reduced_vars) if v.red_op in (red_op, nullop) and bin_op in (v.bin_op, nullop): red_op = v.red_op if red_op is nullop else red_op bin_op = v.bin_op if bin_op is nullop else bin_op new_terms = terms[:i] + v.terms + terms[i+1:] return Contraction(red_op, bin_op, reduced_vars | v.reduced_vars, *new_terms) return None
unfold.register(Contraction, AssociativeOp, AssociativeOp, frozenset, Variadic[Funsor])( lambda r, b, v, *ts: unfold(Contraction, r, b, v, tuple(ts)))
[docs]@interpreter.dispatched_interpretation def optimize(cls, *args): result = optimize.dispatch(cls, *args)(*args) if result is None: result = eager(cls, *args) return result
# TODO set a better value for this REAL_SIZE = 3 # the "size" of a real-valued dimension passed to the path optimizer optimize.register(Contraction, AssociativeOp, AssociativeOp, frozenset, Variadic[Funsor])( lambda r, b, v, *ts: optimize(Contraction, r, b, v, tuple(ts)))
[docs]@optimize.register(Contraction, AssociativeOp, AssociativeOp, frozenset, Funsor, Funsor) @optimize.register(Contraction, AssociativeOp, AssociativeOp, frozenset, Funsor) def eager_contract_base(red_op, bin_op, reduced_vars, *terms): return None
[docs]@optimize.register(Contraction, AssociativeOp, AssociativeOp, frozenset, tuple) def optimize_contract_finitary_funsor(red_op, bin_op, reduced_vars, terms): if red_op is nullop or bin_op is nullop or not (red_op, bin_op) in DISTRIBUTIVE_OPS: return None # build opt_einsum optimizer IR inputs = [frozenset(term.inputs) for term in terms] size_dict = {k: ((REAL_SIZE * v.num_elements) if v.dtype == 'real' else v.dtype) for term in terms for k, v in term.inputs.items()} outputs = frozenset().union(*inputs) - reduced_vars # optimize path with greedy opt_einsum optimizer # TODO switch to new 'auto' strategy path = greedy(inputs, outputs, size_dict) # first prepare a reduce_dim counter to avoid early reduction reduce_dim_counter = collections.Counter() for input in inputs: reduce_dim_counter.update({d: 1 for d in input}) operands = list(terms) for (a, b) in path: b, a = tuple(sorted((a, b), reverse=True)) tb = operands.pop(b) ta = operands.pop(a) # don't reduce a dimension too early - keep a collections.Counter # and only reduce when the dimension is removed from all lhs terms in path reduce_dim_counter.subtract({d: 1 for d in reduced_vars & frozenset(ta.inputs.keys())}) reduce_dim_counter.subtract({d: 1 for d in reduced_vars & frozenset(tb.inputs.keys())}) # reduce variables that don't appear in other terms both_vars = frozenset(ta.inputs.keys()) | frozenset(tb.inputs.keys()) path_end_reduced_vars = frozenset(d for d in reduced_vars & both_vars if reduce_dim_counter[d] == 0) # count new appearance of variables that aren't reduced reduce_dim_counter.update({d: 1 for d in reduced_vars & (both_vars - path_end_reduced_vars)}) path_end = Contraction(red_op if path_end_reduced_vars else nullop, bin_op, path_end_reduced_vars, ta, tb) operands.append(path_end) # reduce any remaining dims, if necessary final_reduced_vars = frozenset(d for (d, count) in reduce_dim_counter.items() if count > 0) & reduced_vars if final_reduced_vars: path_end = path_end.reduce(red_op, final_reduced_vars) return path_end
[docs]def apply_optimizer(x): @interpreter.interpretation(interpreter._INTERPRETATION) def nested_optimize_interpreter(cls, *args): result = optimize.dispatch(cls, *args)(*args) if result is None: result = cls(*args) return result with interpreter.interpretation(unfold): expr = interpreter.reinterpret(x) with interpreter.interpretation(nested_optimize_interpreter): return interpreter.reinterpret(expr)