import py_paddle.swig_paddle as api import topology from data_feeder import DataFeeder import itertools import numpy __all__ = ['Inference', 'infer'] class Inference(object): def __init__(self, output, parameters): topo = topology.Topology(output) gm = api.GradientMachine.createFromConfigProto( topo.proto(), api.CREATE_MODE_TESTING, [api.PARAMETER_VALUE]) for param in gm.getParameters(): val = param.getBuf(api.PARAMETER_VALUE) name = param.getName() assert isinstance(val, api.Vector) val.copyFromNumpyArray(parameters.get(name).flatten()) self.__gradient_machine__ = gm self.__data_types__ = topo.data_type() def iter_infer(self, reader, reader_dict=None): if reader_dict is None: reader_dict = self.default_reader_dict() feeder = DataFeeder(self.__data_types__, reader_dict) self.__gradient_machine__.start() for data_batch in reader(): yield self.__gradient_machine__.forwardTest(feeder(data_batch)) self.__gradient_machine__.finish() def iter_infer_field(self, field, **kwargs): for result in self.iter_infer(**kwargs): yield [each_result[field] for each_result in result] def infer(self, field='value', **kwargs): retv = None for result in self.iter_infer_field(field=field, **kwargs): if retv is None: retv = [[]] * len(result) for i, item in enumerate(result): retv[i].append(item) retv = [numpy.concatenate(out) for out in retv] if len(retv) == 1: return retv[0] else: return retv def default_reader_dict(self): reader_dict = dict() for i, tp in enumerate(self.__data_types__): reader_dict[tp[0]] = i return reader_dict def infer(output, parameters, reader, reader_dict=None, field='value'): inferer = Inference(output=output, parameters=parameters) return inferer.infer(field=field, reader=reader, reader_dict=reader_dict)