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Source code for ding.reward_model.gail_irl_model

from typing import List, Dict, Any
import pickle
import random
from collections.abc import Iterable
from easydict import EasyDict

import torch
import torch.nn as nn
import torch.optim as optim

from ding.utils import REWARD_MODEL_REGISTRY
from .base_reward_model import BaseRewardModel
import torch.nn.functional as F
from functools import partial


def concat_state_action_pairs(iterator):
    """
    Overview:
        Concatenate state and action pairs from input.
    Arguments:
        - iterator (:obj:`Iterable`): Iterables with at least ``obs`` and ``action`` tensor keys.
    Returns:
        - res (:obj:`Torch.tensor`): State and action pairs.
    """
    assert isinstance(iterator, Iterable)
    res = []
    for item in iterator:
        state = item['obs'].flatten()  # to allow 3d obs and actions concatenation
        action = item['action']
        s_a = torch.cat([state, action.float()], dim=-1)
        res.append(s_a)
    return res


def concat_state_action_pairs_one_hot(iterator, action_size: int):
    """
    Overview:
        Concatenate state and action pairs from input. Action values are one-hot encoded
    Arguments:
        - iterator (:obj:`Iterable`): Iterables with at least ``obs`` and ``action`` tensor keys.
    Returns:
        - res (:obj:`Torch.tensor`): State and action pairs.
    """
    assert isinstance(iterator, Iterable)
    res = []
    for item in iterator:
        state = item['obs'].flatten()  # to allow 3d obs and actions concatenation
        action = item['action']
        action = torch.Tensor([int(i == action) for i in range(action_size)])
        s_a = torch.cat([state, action], dim=-1)
        res.append(s_a)
    return res


class RewardModelNetwork(nn.Module):

    def __init__(self, input_size: int, hidden_size: int, output_size: int) -> None:
        super(RewardModelNetwork, self).__init__()
        self.l1 = nn.Linear(input_size, hidden_size)
        self.l2 = nn.Linear(hidden_size, output_size)
        self.a1 = nn.Tanh()
        self.a2 = nn.Sigmoid()

    def forward(self, x: torch.Tensor) -> torch.Tensor:
        out = x
        out = self.l1(out)
        out = self.a1(out)
        out = self.l2(out)
        out = self.a2(out)
        return out


class AtariRewardModelNetwork(nn.Module):

    def __init__(self, input_size: int, action_size: int) -> None:
        super(AtariRewardModelNetwork, self).__init__()
        self.input_size = input_size
        self.action_size = action_size
        self.conv1 = nn.Conv2d(4, 16, 7, stride=3)
        self.conv2 = nn.Conv2d(16, 16, 5, stride=2)
        self.conv3 = nn.Conv2d(16, 16, 3, stride=1)
        self.conv4 = nn.Conv2d(16, 16, 3, stride=1)
        self.fc1 = nn.Linear(784, 64)
        self.fc2 = nn.Linear(64 + self.action_size, 1)  # here we add 1 to take consideration of the action concat
        self.a = nn.Sigmoid()

    def forward(self, x: torch.Tensor) -> torch.Tensor:
        # input: x = [B, 4 x 84 x 84 + self.action_size], last element is action
        actions = x[:, -self.action_size:]  # [B, self.action_size]
        # get observations
        x = x[:, :-self.action_size]
        x = x.reshape([-1] + self.input_size)  # [B, 4, 84, 84]
        x = F.leaky_relu(self.conv1(x))
        x = F.leaky_relu(self.conv2(x))
        x = F.leaky_relu(self.conv3(x))
        x = F.leaky_relu(self.conv4(x))
        x = x.reshape(-1, 784)
        x = F.leaky_relu(self.fc1(x))
        x = torch.cat([x, actions], dim=-1)
        x = self.fc2(x)
        r = self.a(x)
        return r


[docs]@REWARD_MODEL_REGISTRY.register('gail') class GailRewardModel(BaseRewardModel): """ Overview: The Gail reward model class (https://arxiv.org/abs/1606.03476) Interface: ``estimate``, ``train``, ``load_expert_data``, ``collect_data``, ``clear_date``, \ ``__init__``, ``state_dict``, ``load_state_dict``, ``learn`` Config: == ==================== ======== ============= =================================== ======================= ID Symbol Type Default Value Description Other(Shape) == ==================== ======== ============= =================================== ======================= 1 ``type`` str gail | RL policy register name, refer | this arg is optional, | to registry ``POLICY_REGISTRY`` | a placeholder 2 | ``expert_data_`` str expert_data. | Path to the expert dataset | Should be a '.pkl' | ``path`` .pkl | | file 3 | ``learning_rate`` float 0.001 | The step size of gradient descent | 4 | ``update_per_`` int 100 | Number of updates per collect | | ``collect`` | | 5 | ``batch_size`` int 64 | Training batch size | 6 | ``input_size`` int | Size of the input: | | | obs_dim + act_dim | 7 | ``target_new_`` int 64 | Collect steps per iteration | | ``data_count`` | | 8 | ``hidden_size`` int 128 | Linear model hidden size | 9 | ``collect_count`` int 100000 | Expert dataset size | One entry is a (s,a) | | | tuple 10 | ``clear_buffer_`` int 1 | clear buffer per fixed iters | make sure replay | ``per_iters`` | buffer's data count | | isn't too few. | | (code work in entry) == ==================== ======== ============= =================================== ======================= """ config = dict( # (str) RL policy register name, refer to registry ``POLICY_REGISTRY``. type='gail', # (float) The step size of gradient descent. learning_rate=1e-3, # (int) How many updates(iterations) to train after collector's one collection. # Bigger "update_per_collect" means bigger off-policy. # collect data -> update policy-> collect data -> ... update_per_collect=100, # (int) How many samples in a training batch. batch_size=64, # (int) Size of the input: obs_dim + act_dim. input_size=4, # (int) Collect steps per iteration. target_new_data_count=64, # (int) Linear model hidden size. hidden_size=128, # (int) Expert dataset size. collect_count=100000, # (int) Clear buffer per fixed iters. clear_buffer_per_iters=1, ) def __init__(self, config: EasyDict, device: str, tb_logger: 'SummaryWriter') -> None: # noqa """ Overview: Initialize ``self.`` See ``help(type(self))`` for accurate signature. Arguments: - cfg (:obj:`EasyDict`): Training config - device (:obj:`str`): Device usage, i.e. "cpu" or "cuda" - tb_logger (:obj:`SummaryWriter`): Logger, defaultly set as 'SummaryWriter' for model summary """ super(GailRewardModel, self).__init__() self.cfg = config assert device in ["cpu", "cuda"] or "cuda" in device self.device = device self.tb_logger = tb_logger obs_shape = config.input_size if isinstance(obs_shape, int) or len(obs_shape) == 1: self.reward_model = RewardModelNetwork(config.input_size, config.hidden_size, 1) self.concat_state_action_pairs = concat_state_action_pairs elif len(obs_shape) == 3: action_shape = self.cfg.action_size self.reward_model = AtariRewardModelNetwork(config.input_size, action_shape) self.concat_state_action_pairs = partial(concat_state_action_pairs_one_hot, action_size=action_shape) self.reward_model.to(self.device) self.expert_data = [] self.train_data = [] self.expert_data_loader = None self.opt = optim.Adam(self.reward_model.parameters(), config.learning_rate) self.train_iter = 0 self.load_expert_data() def load_expert_data(self) -> None: """ Overview: Getting the expert data from ``config.data_path`` attribute in self Effects: This is a side effect function which updates the expert data attribute \ (i.e. ``self.expert_data``) with ``fn:concat_state_action_pairs`` """ with open(self.cfg.data_path + '/expert_data.pkl', 'rb') as f: self.expert_data_loader: list = pickle.load(f) self.expert_data = self.concat_state_action_pairs(self.expert_data_loader) def state_dict(self) -> Dict[str, Any]: return { 'model': self.reward_model.state_dict(), } def load_state_dict(self, state_dict: Dict[str, Any]) -> None: self.reward_model.load_state_dict(state_dict['model']) def learn(self, train_data: torch.Tensor, expert_data: torch.Tensor) -> float: """ Overview: Helper function for ``train`` which calculates loss for train data and expert data. Arguments: - train_data (:obj:`torch.Tensor`): Data used for training - expert_data (:obj:`torch.Tensor`): Expert data Returns: - Combined loss calculated of reward model from using ``train_data`` and ``expert_data``. """ # calculate loss, here are some hyper-param out_1: torch.Tensor = self.reward_model(train_data) loss_1: torch.Tensor = torch.log(out_1 + 1e-8).mean() out_2: torch.Tensor = self.reward_model(expert_data) loss_2: torch.Tensor = torch.log(1 - out_2 + 1e-8).mean() # log(x) with 0<x<1 is negative, so to reduce this loss we have to minimize the opposite loss: torch.Tensor = -(loss_1 + loss_2) self.opt.zero_grad() loss.backward() self.opt.step() return loss.item() def train(self) -> None: """ Overview: Training the Gail reward model. The training and expert data are randomly sampled with designated\ batch size abstracted from the ``batch_size`` attribute in ``self.cfg`` and \ correspondingly, the ``expert_data`` as well as ``train_data`` attributes initialized ``self` Effects: - This is a side effect function which updates the reward model and increment the train iteration count. """ for _ in range(self.cfg.update_per_collect): sample_expert_data: list = random.sample(self.expert_data, self.cfg.batch_size) sample_train_data: list = random.sample(self.train_data, self.cfg.batch_size) sample_expert_data = torch.stack(sample_expert_data).to(self.device) sample_train_data = torch.stack(sample_train_data).to(self.device) loss = self.learn(sample_train_data, sample_expert_data) self.tb_logger.add_scalar('reward_model/gail_loss', loss, self.train_iter) self.train_iter += 1 def estimate(self, data: list) -> List[Dict]: """ Overview: Estimate reward by rewriting the reward key in each row of the data. Arguments: - data (:obj:`list`): the list of data used for estimation, with at least \ ``obs`` and ``action`` keys. Effects: - This is a side effect function which updates the reward values in place. """ # NOTE: deepcopy reward part of data is very important, # otherwise the reward of data in the replay buffer will be incorrectly modified. train_data_augmented = self.reward_deepcopy(data) res = self.concat_state_action_pairs(train_data_augmented) res = torch.stack(res).to(self.device) with torch.no_grad(): reward = self.reward_model(res).squeeze(-1).cpu() reward = torch.chunk(reward, reward.shape[0], dim=0) for item, rew in zip(train_data_augmented, reward): item['reward'] = -torch.log(rew + 1e-8) return train_data_augmented def collect_data(self, data: list) -> None: """ Overview: Collecting training data formatted by ``fn:concat_state_action_pairs``. Arguments: - data (:obj:`Any`): Raw training data (e.g. some form of states, actions, obs, etc) Effects: - This is a side effect function which updates the data attribute in ``self`` """ self.train_data.extend(self.concat_state_action_pairs(data)) def clear_data(self) -> None: """ Overview: Clearing training data. \ This is a side effect function which clears the data attribute in ``self`` """ self.train_data.clear()