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"""Helper for managing networks.""" |
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import types |
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import inspect |
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import re |
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import uuid |
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import sys |
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import numpy as np |
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import tensorflow as tf |
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|
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from collections import OrderedDict |
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from typing import Any, List, Tuple, Union |
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from . import tfutil |
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from .. import util |
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from .tfutil import TfExpression, TfExpressionEx |
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_import_handlers = [] |
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_import_module_src = dict() |
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|
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def import_handler(handler_func): |
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"""Function decorator for declaring custom import handlers.""" |
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_import_handlers.append(handler_func) |
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return handler_func |
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class Network: |
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"""Generic network abstraction. |
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|
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Acts as a convenience wrapper for a parameterized network construction |
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function, providing several utility methods and convenient access to |
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the inputs/outputs/weights. |
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Network objects can be safely pickled and unpickled for long-term |
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archival purposes. The pickling works reliably as long as the underlying |
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network construction function is defined in a standalone Python module |
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that has no side effects or application-specific imports. |
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|
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Args: |
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name: Network name. Used to select TensorFlow name and variable scopes. |
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func_name: Fully qualified name of the underlying network construction function, or a top-level function object. |
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static_kwargs: Keyword arguments to be passed in to the network construction function. |
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Attributes: |
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name: User-specified name, defaults to build func name if None. |
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scope: Unique TensorFlow scope containing template graph and variables, derived from the user-specified name. |
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static_kwargs: Arguments passed to the user-supplied build func. |
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components: Container for sub-networks. Passed to the build func, and retained between calls. |
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num_inputs: Number of input tensors. |
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num_outputs: Number of output tensors. |
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input_shapes: Input tensor shapes (NC or NCHW), including minibatch dimension. |
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output_shapes: Output tensor shapes (NC or NCHW), including minibatch dimension. |
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input_shape: Short-hand for input_shapes[0]. |
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output_shape: Short-hand for output_shapes[0]. |
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input_templates: Input placeholders in the template graph. |
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output_templates: Output tensors in the template graph. |
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input_names: Name string for each input. |
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output_names: Name string for each output. |
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own_vars: Variables defined by this network (local_name => var), excluding sub-networks. |
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vars: All variables (local_name => var). |
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trainables: All trainable variables (local_name => var). |
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var_global_to_local: Mapping from variable global names to local names. |
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""" |
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def __init__(self, name: str = None, func_name: Any = None, **static_kwargs): |
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tfutil.assert_tf_initialized() |
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assert isinstance(name, str) or name is None |
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assert func_name is not None |
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assert isinstance(func_name, str) or util.is_top_level_function(func_name) |
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assert util.is_pickleable(static_kwargs) |
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self._init_fields() |
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self.name = name |
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self.static_kwargs = util.EasyDict(static_kwargs) |
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if util.is_top_level_function(func_name): |
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func_name = util.get_top_level_function_name(func_name) |
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module, self._build_func_name = util.get_module_from_obj_name(func_name) |
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self._build_func = util.get_obj_from_module(module, self._build_func_name) |
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assert callable(self._build_func) |
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self._build_module_src = _import_module_src.get(module, None) |
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if self._build_module_src is None: |
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self._build_module_src = inspect.getsource(module) |
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self._init_graph() |
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self.reset_own_vars() |
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def _init_fields(self) -> None: |
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self.name = None |
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self.scope = None |
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self.static_kwargs = util.EasyDict() |
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self.components = util.EasyDict() |
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self.num_inputs = 0 |
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self.num_outputs = 0 |
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self.input_shapes = [[]] |
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self.output_shapes = [[]] |
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self.input_shape = [] |
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self.output_shape = [] |
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self.input_templates = [] |
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self.output_templates = [] |
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self.input_names = [] |
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self.output_names = [] |
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self.own_vars = OrderedDict() |
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self.vars = OrderedDict() |
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self.trainables = OrderedDict() |
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self.var_global_to_local = OrderedDict() |
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|
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self._build_func = None |
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self._build_func_name = None |
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self._build_module_src = None |
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self._run_cache = dict() |
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def _init_graph(self) -> None: |
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self.input_names = [] |
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for param in inspect.signature(self._build_func).parameters.values(): |
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if param.kind == param.POSITIONAL_OR_KEYWORD and param.default is param.empty: |
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self.input_names.append(param.name) |
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self.num_inputs = len(self.input_names) |
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assert self.num_inputs >= 1 |
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if self.name is None: |
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self.name = self._build_func_name |
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assert re.match("^[A-Za-z0-9_.\\-]*$", self.name) |
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with tf.name_scope(None): |
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self.scope = tf.get_default_graph().unique_name(self.name, mark_as_used=True) |
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build_kwargs = dict(self.static_kwargs) |
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build_kwargs["is_template_graph"] = True |
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build_kwargs["components"] = self.components |
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with tfutil.absolute_variable_scope(self.scope, reuse=False), tfutil.absolute_name_scope(self.scope): |
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assert tf.get_variable_scope().name == self.scope |
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assert tf.get_default_graph().get_name_scope() == self.scope |
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with tf.control_dependencies(None): |
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self.input_templates = [tf.placeholder(tf.float32, name=name) for name in self.input_names] |
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out_expr = self._build_func(*self.input_templates, **build_kwargs) |
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assert tfutil.is_tf_expression(out_expr) or isinstance(out_expr, tuple) |
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self.output_templates = [out_expr] if tfutil.is_tf_expression(out_expr) else list(out_expr) |
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self.num_outputs = len(self.output_templates) |
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assert self.num_outputs >= 1 |
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assert all(tfutil.is_tf_expression(t) for t in self.output_templates) |
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if any(t.shape.ndims is None for t in self.input_templates): |
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raise ValueError("Network input shapes not defined. Please call x.set_shape() for each input.") |
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if any(t.shape.ndims is None for t in self.output_templates): |
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raise ValueError("Network output shapes not defined. Please call x.set_shape() where applicable.") |
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if any(not isinstance(comp, Network) for comp in self.components.values()): |
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raise ValueError("Components of a Network must be Networks themselves.") |
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if len(self.components) != len(set(comp.name for comp in self.components.values())): |
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raise ValueError("Components of a Network must have unique names.") |
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self.input_shapes = [t.shape.as_list() for t in self.input_templates] |
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self.output_shapes = [t.shape.as_list() for t in self.output_templates] |
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self.input_shape = self.input_shapes[0] |
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self.output_shape = self.output_shapes[0] |
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self.output_names = [t.name.split("/")[-1].split(":")[0] for t in self.output_templates] |
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self.own_vars = OrderedDict((var.name[len(self.scope) + 1:].split(":")[0], var) for var in tf.global_variables(self.scope + "/")) |
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self.vars = OrderedDict(self.own_vars) |
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self.vars.update((comp.name + "/" + name, var) for comp in self.components.values() for name, var in comp.vars.items()) |
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self.trainables = OrderedDict((name, var) for name, var in self.vars.items() if var.trainable) |
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self.var_global_to_local = OrderedDict((var.name.split(":")[0], name) for name, var in self.vars.items()) |
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def reset_own_vars(self) -> None: |
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"""Re-initialize all variables of this network, excluding sub-networks.""" |
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tfutil.run([var.initializer for var in self.own_vars.values()]) |
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def reset_vars(self) -> None: |
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"""Re-initialize all variables of this network, including sub-networks.""" |
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tfutil.run([var.initializer for var in self.vars.values()]) |
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def reset_trainables(self) -> None: |
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"""Re-initialize all trainable variables of this network, including sub-networks.""" |
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tfutil.run([var.initializer for var in self.trainables.values()]) |
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def get_output_for(self, *in_expr: TfExpression, return_as_list: bool = False, **dynamic_kwargs) -> Union[TfExpression, List[TfExpression]]: |
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"""Construct TensorFlow expression(s) for the output(s) of this network, given the input expression(s).""" |
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assert len(in_expr) == self.num_inputs |
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assert not all(expr is None for expr in in_expr) |
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build_kwargs = dict(self.static_kwargs) |
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build_kwargs.update(dynamic_kwargs) |
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build_kwargs["is_template_graph"] = False |
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build_kwargs["components"] = self.components |
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with tfutil.absolute_variable_scope(self.scope, reuse=True), tf.name_scope(self.name): |
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assert tf.get_variable_scope().name == self.scope |
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valid_inputs = [expr for expr in in_expr if expr is not None] |
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final_inputs = [] |
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for expr, name, shape in zip(in_expr, self.input_names, self.input_shapes): |
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if expr is not None: |
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expr = tf.identity(expr, name=name) |
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else: |
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expr = tf.zeros([tf.shape(valid_inputs[0])[0]] + shape[1:], name=name) |
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final_inputs.append(expr) |
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out_expr = self._build_func(*final_inputs, **build_kwargs) |
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for expr, final in zip(in_expr, final_inputs): |
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if isinstance(expr, tf.Tensor): |
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expr.set_shape(final.shape) |
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assert tfutil.is_tf_expression(out_expr) or isinstance(out_expr, tuple) |
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if return_as_list: |
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out_expr = [out_expr] if tfutil.is_tf_expression(out_expr) else list(out_expr) |
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return out_expr |
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def get_var_local_name(self, var_or_global_name: Union[TfExpression, str]) -> str: |
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"""Get the local name of a given variable, without any surrounding name scopes.""" |
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assert tfutil.is_tf_expression(var_or_global_name) or isinstance(var_or_global_name, str) |
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global_name = var_or_global_name if isinstance(var_or_global_name, str) else var_or_global_name.name |
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return self.var_global_to_local[global_name] |
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def find_var(self, var_or_local_name: Union[TfExpression, str]) -> TfExpression: |
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"""Find variable by local or global name.""" |
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assert tfutil.is_tf_expression(var_or_local_name) or isinstance(var_or_local_name, str) |
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return self.vars[var_or_local_name] if isinstance(var_or_local_name, str) else var_or_local_name |
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def get_var(self, var_or_local_name: Union[TfExpression, str]) -> np.ndarray: |
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"""Get the value of a given variable as NumPy array. |
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Note: This method is very inefficient -- prefer to use tflib.run(list_of_vars) whenever possible.""" |
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return self.find_var(var_or_local_name).eval() |
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def set_var(self, var_or_local_name: Union[TfExpression, str], new_value: Union[int, float, np.ndarray]) -> None: |
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"""Set the value of a given variable based on the given NumPy array. |
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Note: This method is very inefficient -- prefer to use tflib.set_vars() whenever possible.""" |
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tfutil.set_vars({self.find_var(var_or_local_name): new_value}) |
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def __getstate__(self) -> dict: |
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"""Pickle export.""" |
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state = dict() |
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state["version"] = 4 |
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state["name"] = self.name |
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state["static_kwargs"] = dict(self.static_kwargs) |
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state["components"] = dict(self.components) |
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state["build_module_src"] = self._build_module_src |
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state["build_func_name"] = self._build_func_name |
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state["variables"] = list(zip(self.own_vars.keys(), tfutil.run(list(self.own_vars.values())))) |
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return state |
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def __setstate__(self, state: dict) -> None: |
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"""Pickle import.""" |
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tfutil.assert_tf_initialized() |
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self._init_fields() |
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for handler in _import_handlers: |
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state = handler(state) |
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assert state["version"] in [2, 3, 4] |
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self.name = state["name"] |
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self.static_kwargs = util.EasyDict(state["static_kwargs"]) |
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self.components = util.EasyDict(state.get("components", {})) |
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self._build_module_src = state["build_module_src"] |
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self._build_func_name = state["build_func_name"] |
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module_name = "_tflib_network_import_" + uuid.uuid4().hex |
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module = types.ModuleType(module_name) |
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sys.modules[module_name] = module |
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_import_module_src[module] = self._build_module_src |
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exec(self._build_module_src, module.__dict__) |
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self._build_func = util.get_obj_from_module(module, self._build_func_name) |
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assert callable(self._build_func) |
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self._init_graph() |
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self.reset_own_vars() |
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tfutil.set_vars({self.find_var(name): value for name, value in state["variables"]}) |
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def clone(self, name: str = None, **new_static_kwargs) -> "Network": |
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"""Create a clone of this network with its own copy of the variables.""" |
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net = object.__new__(Network) |
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net._init_fields() |
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net.name = name if name is not None else self.name |
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net.static_kwargs = util.EasyDict(self.static_kwargs) |
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net.static_kwargs.update(new_static_kwargs) |
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net._build_module_src = self._build_module_src |
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net._build_func_name = self._build_func_name |
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net._build_func = self._build_func |
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net._init_graph() |
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net.copy_vars_from(self) |
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return net |
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def copy_own_vars_from(self, src_net: "Network") -> None: |
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"""Copy the values of all variables from the given network, excluding sub-networks.""" |
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names = [name for name in self.own_vars.keys() if name in src_net.own_vars] |
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tfutil.set_vars(tfutil.run({self.vars[name]: src_net.vars[name] for name in names})) |
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def copy_vars_from(self, src_net: "Network") -> None: |
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"""Copy the values of all variables from the given network, including sub-networks.""" |
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names = [name for name in self.vars.keys() if name in src_net.vars] |
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tfutil.set_vars(tfutil.run({self.vars[name]: src_net.vars[name] for name in names})) |
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def copy_trainables_from(self, src_net: "Network") -> None: |
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"""Copy the values of all trainable variables from the given network, including sub-networks.""" |
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names = [name for name in self.trainables.keys() if name in src_net.trainables] |
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tfutil.set_vars(tfutil.run({self.vars[name]: src_net.vars[name] for name in names})) |
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def convert(self, new_func_name: str, new_name: str = None, **new_static_kwargs) -> "Network": |
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"""Create new network with the given parameters, and copy all variables from this network.""" |
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if new_name is None: |
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new_name = self.name |
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static_kwargs = dict(self.static_kwargs) |
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static_kwargs.update(new_static_kwargs) |
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net = Network(name=new_name, func_name=new_func_name, **static_kwargs) |
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net.copy_vars_from(self) |
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return net |
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def setup_as_moving_average_of(self, src_net: "Network", beta: TfExpressionEx = 0.99, beta_nontrainable: TfExpressionEx = 0.0) -> tf.Operation: |
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"""Construct a TensorFlow op that updates the variables of this network |
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to be slightly closer to those of the given network.""" |
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with tfutil.absolute_name_scope(self.scope + "/_MovingAvg"): |
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ops = [] |
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for name, var in self.vars.items(): |
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if name in src_net.vars: |
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cur_beta = beta if name in self.trainables else beta_nontrainable |
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new_value = tfutil.lerp(src_net.vars[name], var, cur_beta) |
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ops.append(var.assign(new_value)) |
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return tf.group(*ops) |
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def run(self, |
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*in_arrays: Tuple[Union[np.ndarray, None], ...], |
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input_transform: dict = None, |
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output_transform: dict = None, |
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return_as_list: bool = False, |
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print_progress: bool = False, |
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minibatch_size: int = None, |
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num_gpus: int = 1, |
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assume_frozen: bool = False, |
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**dynamic_kwargs) -> Union[np.ndarray, Tuple[np.ndarray, ...], List[np.ndarray]]: |
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"""Run this network for the given NumPy array(s), and return the output(s) as NumPy array(s). |
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Args: |
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input_transform: A dict specifying a custom transformation to be applied to the input tensor(s) before evaluating the network. |
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The dict must contain a 'func' field that points to a top-level function. The function is called with the input |
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TensorFlow expression(s) as positional arguments. Any remaining fields of the dict will be passed in as kwargs. |
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output_transform: A dict specifying a custom transformation to be applied to the output tensor(s) after evaluating the network. |
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The dict must contain a 'func' field that points to a top-level function. The function is called with the output |
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TensorFlow expression(s) as positional arguments. Any remaining fields of the dict will be passed in as kwargs. |
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return_as_list: True = return a list of NumPy arrays, False = return a single NumPy array, or a tuple if there are multiple outputs. |
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print_progress: Print progress to the console? Useful for very large input arrays. |
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minibatch_size: Maximum minibatch size to use, None = disable batching. |
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num_gpus: Number of GPUs to use. |
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assume_frozen: Improve multi-GPU performance by assuming that the trainable parameters will remain changed between calls. |
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dynamic_kwargs: Additional keyword arguments to be passed into the network build function. |
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""" |
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assert len(in_arrays) == self.num_inputs |
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assert not all(arr is None for arr in in_arrays) |
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assert input_transform is None or util.is_top_level_function(input_transform["func"]) |
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assert output_transform is None or util.is_top_level_function(output_transform["func"]) |
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output_transform, dynamic_kwargs = _handle_legacy_output_transforms(output_transform, dynamic_kwargs) |
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num_items = in_arrays[0].shape[0] |
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if minibatch_size is None: |
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minibatch_size = num_items |
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|
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key = dict(input_transform=input_transform, output_transform=output_transform, num_gpus=num_gpus, assume_frozen=assume_frozen, dynamic_kwargs=dynamic_kwargs) |
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def unwind_key(obj): |
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if isinstance(obj, dict): |
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return [(key, unwind_key(value)) for key, value in sorted(obj.items())] |
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if callable(obj): |
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return util.get_top_level_function_name(obj) |
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return obj |
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key = repr(unwind_key(key)) |
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|
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if key not in self._run_cache: |
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with tfutil.absolute_name_scope(self.scope + "/_Run"), tf.control_dependencies(None): |
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with tf.device("/cpu:0"): |
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in_expr = [tf.placeholder(tf.float32, name=name) for name in self.input_names] |
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in_split = list(zip(*[tf.split(x, num_gpus) for x in in_expr])) |
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|
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out_split = [] |
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for gpu in range(num_gpus): |
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with tf.device("/gpu:%d" % gpu): |
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net_gpu = self.clone() if assume_frozen else self |
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in_gpu = in_split[gpu] |
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|
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if input_transform is not None: |
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in_kwargs = dict(input_transform) |
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in_gpu = in_kwargs.pop("func")(*in_gpu, **in_kwargs) |
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in_gpu = [in_gpu] if tfutil.is_tf_expression(in_gpu) else list(in_gpu) |
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|
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assert len(in_gpu) == self.num_inputs |
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out_gpu = net_gpu.get_output_for(*in_gpu, return_as_list=True, **dynamic_kwargs) |
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|
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if output_transform is not None: |
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out_kwargs = dict(output_transform) |
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out_gpu = out_kwargs.pop("func")(*out_gpu, **out_kwargs) |
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out_gpu = [out_gpu] if tfutil.is_tf_expression(out_gpu) else list(out_gpu) |
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assert len(out_gpu) == self.num_outputs |
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out_split.append(out_gpu) |
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|
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with tf.device("/cpu:0"): |
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out_expr = [tf.concat(outputs, axis=0) for outputs in zip(*out_split)] |
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self._run_cache[key] = in_expr, out_expr |
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in_expr, out_expr = self._run_cache[key] |
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out_arrays = [np.empty([num_items] + expr.shape.as_list()[1:], expr.dtype.name) for expr in out_expr] |
|
|
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for mb_begin in range(0, num_items, minibatch_size): |
|
if print_progress: |
|
print("\r%d / %d" % (mb_begin, num_items), end="") |
|
|
|
mb_end = min(mb_begin + minibatch_size, num_items) |
|
mb_num = mb_end - mb_begin |
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mb_in = [src[mb_begin : mb_end] if src is not None else np.zeros([mb_num] + shape[1:]) for src, shape in zip(in_arrays, self.input_shapes)] |
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mb_out = tf.get_default_session().run(out_expr, dict(zip(in_expr, mb_in))) |
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|
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for dst, src in zip(out_arrays, mb_out): |
|
dst[mb_begin: mb_end] = src |
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|
|
if print_progress: |
|
print("\r%d / %d" % (num_items, num_items)) |
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|
|
if not return_as_list: |
|
out_arrays = out_arrays[0] if len(out_arrays) == 1 else tuple(out_arrays) |
|
return out_arrays |
|
|
|
def list_ops(self) -> List[TfExpression]: |
|
include_prefix = self.scope + "/" |
|
exclude_prefix = include_prefix + "_" |
|
ops = tf.get_default_graph().get_operations() |
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ops = [op for op in ops if op.name.startswith(include_prefix)] |
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ops = [op for op in ops if not op.name.startswith(exclude_prefix)] |
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return ops |
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|
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def list_layers(self) -> List[Tuple[str, TfExpression, List[TfExpression]]]: |
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"""Returns a list of (layer_name, output_expr, trainable_vars) tuples corresponding to |
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individual layers of the network. Mainly intended to be used for reporting.""" |
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layers = [] |
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|
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def recurse(scope, parent_ops, parent_vars, level): |
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|
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if any(p in scope for p in ["/Shape", "/strided_slice", "/Cast", "/concat", "/Assign"]): |
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return |
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|
|
|
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global_prefix = scope + "/" |
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local_prefix = global_prefix[len(self.scope) + 1:] |
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cur_ops = [op for op in parent_ops if op.name.startswith(global_prefix) or op.name == global_prefix[:-1]] |
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cur_vars = [(name, var) for name, var in parent_vars if name.startswith(local_prefix) or name == local_prefix[:-1]] |
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if not cur_ops and not cur_vars: |
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return |
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|
|
|
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for var in [op for op in cur_ops if op.type.startswith("Variable")]: |
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var_prefix = var.name + "/" |
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cur_ops = [op for op in cur_ops if not op.name.startswith(var_prefix)] |
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|
|
|
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contains_direct_ops = any("/" not in op.name[len(global_prefix):] and op.type not in ["Identity", "Cast", "Transpose"] for op in cur_ops) |
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if (level == 0 or not contains_direct_ops) and (len(cur_ops) + len(cur_vars)) > 1: |
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visited = set() |
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for rel_name in [op.name[len(global_prefix):] for op in cur_ops] + [name[len(local_prefix):] for name, _var in cur_vars]: |
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token = rel_name.split("/")[0] |
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if token not in visited: |
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recurse(global_prefix + token, cur_ops, cur_vars, level + 1) |
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visited.add(token) |
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return |
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|
|
|
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layer_name = scope[len(self.scope) + 1:] |
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layer_output = cur_ops[-1].outputs[0] if cur_ops else cur_vars[-1][1] |
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layer_trainables = [var for _name, var in cur_vars if var.trainable] |
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layers.append((layer_name, layer_output, layer_trainables)) |
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|
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recurse(self.scope, self.list_ops(), list(self.vars.items()), 0) |
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return layers |
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|
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def print_layers(self, title: str = None, hide_layers_with_no_params: bool = False) -> None: |
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"""Print a summary table of the network structure.""" |
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rows = [[title if title is not None else self.name, "Params", "OutputShape", "WeightShape"]] |
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rows += [["---"] * 4] |
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total_params = 0 |
|
|
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for layer_name, layer_output, layer_trainables in self.list_layers(): |
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num_params = sum(int(np.prod(var.shape.as_list())) for var in layer_trainables) |
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weights = [var for var in layer_trainables if var.name.endswith("/weight:0")] |
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weights.sort(key=lambda x: len(x.name)) |
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if len(weights) == 0 and len(layer_trainables) == 1: |
|
weights = layer_trainables |
|
total_params += num_params |
|
|
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if not hide_layers_with_no_params or num_params != 0: |
|
num_params_str = str(num_params) if num_params > 0 else "-" |
|
output_shape_str = str(layer_output.shape) |
|
weight_shape_str = str(weights[0].shape) if len(weights) >= 1 else "-" |
|
rows += [[layer_name, num_params_str, output_shape_str, weight_shape_str]] |
|
|
|
rows += [["---"] * 4] |
|
rows += [["Total", str(total_params), "", ""]] |
|
|
|
widths = [max(len(cell) for cell in column) for column in zip(*rows)] |
|
print() |
|
for row in rows: |
|
print(" ".join(cell + " " * (width - len(cell)) for cell, width in zip(row, widths))) |
|
print() |
|
|
|
def setup_weight_histograms(self, title: str = None) -> None: |
|
"""Construct summary ops to include histograms of all trainable parameters in TensorBoard.""" |
|
if title is None: |
|
title = self.name |
|
|
|
with tf.name_scope(None), tf.device(None), tf.control_dependencies(None): |
|
for local_name, var in self.trainables.items(): |
|
if "/" in local_name: |
|
p = local_name.split("/") |
|
name = title + "_" + p[-1] + "/" + "_".join(p[:-1]) |
|
else: |
|
name = title + "_toplevel/" + local_name |
|
|
|
tf.summary.histogram(name, var) |
|
|
|
|
|
|
|
|
|
_print_legacy_warning = True |
|
|
|
def _handle_legacy_output_transforms(output_transform, dynamic_kwargs): |
|
global _print_legacy_warning |
|
legacy_kwargs = ["out_mul", "out_add", "out_shrink", "out_dtype"] |
|
if not any(kwarg in dynamic_kwargs for kwarg in legacy_kwargs): |
|
return output_transform, dynamic_kwargs |
|
|
|
if _print_legacy_warning: |
|
_print_legacy_warning = False |
|
print() |
|
print("WARNING: Old-style output transformations in Network.run() are deprecated.") |
|
print("Consider using 'output_transform=dict(func=tflib.convert_images_to_uint8)'") |
|
print("instead of 'out_mul=127.5, out_add=127.5, out_dtype=np.uint8'.") |
|
print() |
|
assert output_transform is None |
|
|
|
new_kwargs = dict(dynamic_kwargs) |
|
new_transform = {kwarg: new_kwargs.pop(kwarg) for kwarg in legacy_kwargs if kwarg in dynamic_kwargs} |
|
new_transform["func"] = _legacy_output_transform_func |
|
return new_transform, new_kwargs |
|
|
|
def _legacy_output_transform_func(*expr, out_mul=1.0, out_add=0.0, out_shrink=1, out_dtype=None): |
|
if out_mul != 1.0: |
|
expr = [x * out_mul for x in expr] |
|
|
|
if out_add != 0.0: |
|
expr = [x + out_add for x in expr] |
|
|
|
if out_shrink > 1: |
|
ksize = [1, 1, out_shrink, out_shrink] |
|
expr = [tf.nn.avg_pool(x, ksize=ksize, strides=ksize, padding="VALID", data_format="NCHW") for x in expr] |
|
|
|
if out_dtype is not None: |
|
if tf.as_dtype(out_dtype).is_integer: |
|
expr = [tf.round(x) for x in expr] |
|
expr = [tf.saturate_cast(x, out_dtype) for x in expr] |
|
return expr |
|
|
