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AgileRL is a deep reinforcement learning library focused on improving RL development through RLOps.

Project description

AgileRL

Reinforcement learning streamlined.
Easier and faster reinforcement learning with RLOps. Visit our website. View documentation.

Documentation Status

This is a Deep Reinforcement Learning library focused on improving development by introducing RLOps - MLOps for reinforcement learning.

This library is initially focused on reducing the time taken for training models and hyperparameter optimisation (HPO) by pioneering evolutionary HPO techniques for reinforcement learning.
Evolutionary HPO has been shown to drastically reduce overall training times by automatically converging on optimal hyperparameters, without requiring numerous training runs.
We are constantly adding more algorithms, with a view to add hierarchical and multi-agent algorithms soon.

Get Started

Install as a package with pip:

git clone https://github.com/AgileRL/AgileRL.git
pip install -e AgileRL

Or install in development mode: (Recommended due to nascent nature of this library)

git clone https://github.com/AgileRL/AgileRL.git && cd AgileRL
pip install -r requirements.txt

Run benchmarking demo:

python benchmarking.py

Algorithms implemented (more coming soon!)

  • DQN
  • DDPG

Train an agent

Before starting training, there are some meta-hyperparameters and settings that must be set. These are defined in INIT_HP, for general parameters, and MUTATION_PARAMS, which define the evolutionary probabilities. For example:

INIT_HP = {
    'ENV_NAME': 'LunarLander-v2',   # Gym environment name
    'ALGO': 'DQN',                  # Algorithm
    'HIDDEN_SIZE': [64,64],         # Actor network hidden size
    'BATCH_SIZE': 256,              # Batch size
    'LR': 1e-3,                     # Learning rate
    'EPISODES': 2000,               # Max no. episodes
    'TARGET_SCORE': 200.,           # Early training stop at avg score of last 100 episodes
    'GAMMA': 0.99,                  # Discount factor
    'MEMORY_SIZE': 10000,           # Max memory buffer size
    'LEARN_STEP': 1,                # Learning frequency
    'TAU': 1e-3,                    # For soft update of target parameters
    'TOURN_SIZE': 2,                # Tournament size
    'ELITISM': True,                # Elitism in tournament selection
    'POP_SIZE': 6,                  # Population size
    'EVO_EPOCHS': 20,               # Evolution frequency
    'POLICY_FREQ': 2,               # Policy network update frequency
    'WANDB': True                   # Log with Weights and Biases
}
MUTATION_PARAMS = {
    # Relative probabilities
    'NO_MUT': 0.4,                              # No mutation
    'ARCH_MUT': 0.2,                            # Architecture mutation
    'NEW_LAYER': 0.2,                           # New layer mutation
    'PARAMS_MUT': 0.2,                          # Network parameters mutation
    'ACT_MUT': 0,                               # Activation layer mutation
    'RL_HP_MUT': 0.2,                           # Learning HP mutation
    'RL_HP_SELECTION': ['lr', 'batch_size'],    # Learning HPs to choose from
    'MUT_SD': 0.1,                              # Mutation strength
    'RAND_SEED': 1,                             # Random seed
}

First, use utils.initialPopulation to create a list of agents - our population that will evolve and mutate to the optimal hyperparameters.

device = torch.device("cuda" if torch.cuda.is_available() else "cpu")
env = gym.make(INIT_HP['ENV_NAME'], render_mode='rgb_array')
num_states = env.observation_space.shape[0]
try:
    num_actions = env.action_space.n
except:
    num_actions = env.action_space.shape[0]

agent_pop = initialPopulation(INIT_HP['ALGO'],
  num_states,
  num_actions,
  INIT_HP,
  INIT_HP['POP_SIZE'],
  device=device)

Next, create the tournament, mutations and experience replay buffer objects that allow agents to share memory and efficiently perform evolutionary HPO.

field_names = ["state", "action", "reward", "next_state", "done"]
memory = ReplayBuffer(num_actions, INIT_HP['MEMORY_SIZE'], field_names=field_names, device=device)

tournament = TournamentSelection(INIT_HP['TOURN_SIZE'],
    INIT_HP['ELITISM'],
    INIT_HP['POP_SIZE'],
    INIT_HP['EVO_EPOCHS'])
    
mutations = Mutations(algo=INIT_HP['ALGO'],
    no_mutation=MUTATION_PARAMS['NO_MUT'], 
    architecture=MUTATION_PARAMS['ARCH_MUT'], 
    new_layer_prob=MUTATION_PARAMS['NEW_LAYER'], 
    parameters=MUTATION_PARAMS['PARAMS_MUT'], 
    activation=MUTATION_PARAMS['ACT_MUT'], 
    rl_hp=MUTATION_PARAMS['RL_HP_MUT'], 
    rl_hp_selection=MUTATION_PARAMS['RL_HP_SELECTION'], 
    mutation_sd=MUTATION_PARAMS['MUT_SD'], 
    rand_seed=MUTATION_PARAMS['RAND_SEED'],
    device=device)

The easiest training loop implementation is to use our training.train() function. It requires the agent have functions getAction() and learn().

trained_pop, pop_fitnesses = train(env,
    INIT_HP['ENV_NAME'],
    INIT_HP['ALGO'],
    agent_pop,
    memory=memory,
    n_episodes=INIT_HP['EPISODES'],
    evo_epochs=INIT_HP['EVO_EPOCHS'],
    evo_loop=1,
    target=INIT_HP['TARGET_SCORE'],
    chkpt=INIT_HP['SAVE_CHKPT'],
    tournament=tournament,
    mutation=mutations,
    wb=INIT_HP['WANDB'],
    device=device)

Custom Training Loop

Alternatively, use a custom training loop. Combining all of the above:

from agilerl.utils import initialPopulation
from agilerl.components.replay_buffer import ReplayBuffer
from agilerl.hpo.tournament import TournamentSelection
from agilerl.hpo.mutation import Mutations
import gymnasium as gym
import numpy as np
import torch

INIT_HP = {
            'HIDDEN_SIZE': [64,64], # Actor network hidden size
            'BATCH_SIZE': 128,      # Batch size
            'LR': 1e-3,             # Learning rate
            'GAMMA': 0.99,          # Discount factor
            'LEARN_STEP': 1,        # Learning frequency
            'TAU': 1e-3             # For soft update of target network parameters
            }

pop = initialPopulation(algo='DQN',           # Algorithm
                        num_states=8,         # State dimension
                        num_actions=4,        # Action dimension
                        INIT_HP=INIT_HP,      # Initial hyperparameters
                        population_size=6,    # Population size
                        device=torch.device("cuda"))

field_names = ["state", "action", "reward", "next_state", "done"]
memory = ReplayBuffer(n_actions=4,              # Number of agent actions
                      memory_size=10000,        # Max replay buffer size
                      field_names=field_names,  # Field names to store in memory
                      device=torch.device("cuda"))

tournament = TournamentSelection(tournament_size=2, # Tournament selection size
                                 elitism=True,      # Elitism in tournament selection
                                 population_size=6, # Population size
                                 evo_step=1)        # Evaluate using last N fitness scores

mutations = Mutations(algo='DQN',                           # Algorithm
                      no_mutation=0.4,                      # No mutation
                      architecture=0.2,                     # Architecture mutation
                      new_layer_prob=0.2,                   # New layer mutation
                      parameters=0.2,                       # Network parameters mutation
                      activation=0,                         # Activation layer mutation
                      rl_hp=0.2,                            # Learning HP mutation
                      rl_hp_selection=['lr', 'batch_size'], # Learning HPs to choose from
                      mutation_sd=0.1,                      # Mutation strength
                      rand_seed=1,                          # Random seed
                      device=torch.device("cuda"))

max_episodes = 1000 # Max training episodes
max_steps = 500     # Max steps per episode

# Exploration params
eps_start = 1.0     # Max exploration
eps_end = 0.1       # Min exploration
eps_decay = 0.995   # Decay per episode
epsilon = eps_start

evo_epochs = 5      # Evolution frequency
evo_loop = 1        # Number of evaluation episodes

env = gym.make('LunarLander-v2', render_mode='rgb_array')   # Create environment

# TRAINING LOOP
for idx_epi in range(max_episodes):
    for agent in pop:   # Loop through population
        state = env.reset()[0]  # Reset environment at start of episode
        score = 0
        for idx_step in range(max_steps):
            action = agent.getAction(state, epsilon)    # Get next action from agent
            next_state, reward, done, _, _ = env.step(action)   # Act in environment
            
            # Save experience to replay buffer
            memory.save2memory(state, action, reward, next_state, done)

            # Learn according to learning frequency
            if memory.counter % agent.learn_step == 0 and len(memory) >= agent.batch_size:
                experiences = memory.sample(agent.batch_size) # Sample replay buffer
                agent.learn(experiences)    # Learn according to agent's RL algorithm
            
            state = next_state
            score += reward

            if done:
                break

    epsilon = max(eps_end, epsilon*eps_decay) # Update epsilon for exploration

    # Now evolve population if necessary
    if (idx_epi+1) % evo_epochs == 0:
        
        # Evaluate population
        fitnesses = [agent.test(env, max_steps=max_steps, loop=evo_loop) for agent in pop]

        print(f'Episode {idx_epi+1}/{max_episodes}')
        print(f'Fitnesses: {["%.2f"%fitness for fitness in fitnesses]}')
        print(f'100 fitness avgs: {["%.2f"%np.mean(agent.fitness[-100:]) for agent in pop]}')

        # Tournament selection and population mutation
        elite, pop = tournament.select(pop)
        pop = mutations.mutation(pop)

View documentation.

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