Exemple #1
0
def learn(env,
          policy_func,
          reward_giver,
          expert_dataset,
          rank,
          pretrained,
          pretrained_weight,
          *,
          g_step,
          d_step,
          entcoeff,
          save_per_iter,
          ckpt_dir,
          log_dir,
          timesteps_per_batch,
          task_name,
          gamma,
          lam,
          max_kl,
          cg_iters,
          cg_damping=1e-2,
          vf_stepsize=3e-4,
          d_stepsize=3e-4,
          vf_iters=3,
          max_timesteps=0,
          max_episodes=0,
          max_iters=0,
          callback=None):

    nworkers = MPI.COMM_WORLD.Get_size()
    rank = MPI.COMM_WORLD.Get_rank()
    np.set_printoptions(precision=3)
    # Setup losses and stuff
    # ----------------------------------------
    ob_space = env.observation_space
    ac_space = env.action_space
    pi = policy_func("pi",
                     ob_space,
                     ac_space,
                     reuse=(pretrained_weight != None))
    oldpi = policy_func("oldpi", ob_space, ac_space)
    atarg = tf.placeholder(
        dtype=tf.float32,
        shape=[None])  # Target advantage function (if applicable)
    ret = tf.placeholder(dtype=tf.float32, shape=[None])  # Empirical return

    ob = U.get_placeholder_cached(name="ob")
    ac = pi.pdtype.sample_placeholder([None])

    kloldnew = oldpi.pd.kl(pi.pd)
    ent = pi.pd.entropy()
    meankl = tf.reduce_mean(kloldnew)
    meanent = tf.reduce_mean(ent)
    entbonus = entcoeff * meanent

    vferr = tf.reduce_mean(tf.square(pi.vpred - ret))

    ratio = tf.exp(pi.pd.logp(ac) -
                   oldpi.pd.logp(ac))  # advantage * pnew / pold
    surrgain = tf.reduce_mean(ratio * atarg)

    optimgain = surrgain + entbonus
    losses = [optimgain, meankl, entbonus, surrgain, meanent]
    loss_names = ["optimgain", "meankl", "entloss", "surrgain", "entropy"]

    dist = meankl

    all_var_list = pi.get_trainable_variables()
    var_list = [
        v for v in all_var_list
        if v.name.startswith("pi/pol") or v.name.startswith("pi/logstd")
    ]
    vf_var_list = [v for v in all_var_list if v.name.startswith("pi/vff")]
    assert len(var_list) == len(vf_var_list) + 1
    d_adam = MpiAdam(reward_giver.get_trainable_variables())
    vfadam = MpiAdam(vf_var_list)

    get_flat = U.GetFlat(var_list)
    set_from_flat = U.SetFromFlat(var_list)
    klgrads = tf.gradients(dist, var_list)
    flat_tangent = tf.placeholder(dtype=tf.float32,
                                  shape=[None],
                                  name="flat_tan")
    shapes = [var.get_shape().as_list() for var in var_list]
    start = 0
    tangents = []
    for shape in shapes:
        sz = U.intprod(shape)
        tangents.append(tf.reshape(flat_tangent[start:start + sz], shape))
        start += sz
    gvp = tf.add_n([
        tf.reduce_sum(g * tangent)
        for (g, tangent) in zipsame(klgrads, tangents)
    ])  # pylint: disable=E1111
    fvp = U.flatgrad(gvp, var_list)

    assign_old_eq_new = U.function(
        [], [],
        updates=[
            tf.assign(oldv, newv)
            for (oldv,
                 newv) in zipsame(oldpi.get_variables(), pi.get_variables())
        ])
    compute_losses = U.function([ob, ac, atarg], losses)
    compute_lossandgrad = U.function([ob, ac, atarg], losses +
                                     [U.flatgrad(optimgain, var_list)])
    compute_fvp = U.function([flat_tangent, ob, ac, atarg], fvp)
    compute_vflossandgrad = U.function([ob, ret],
                                       U.flatgrad(vferr, vf_var_list))

    @contextmanager
    def timed(msg):
        if rank == 0:
            print(colorize(msg, color='magenta'))
            tstart = time.time()
            yield
            print(
                colorize("done in %.3f seconds" % (time.time() - tstart),
                         color='magenta'))
        else:
            yield

    def allmean(x):
        assert isinstance(x, np.ndarray)
        out = np.empty_like(x)
        MPI.COMM_WORLD.Allreduce(x, out, op=MPI.SUM)
        out /= nworkers
        return out

    U.initialize()
    th_init = get_flat()
    MPI.COMM_WORLD.Bcast(th_init, root=0)
    set_from_flat(th_init)
    d_adam.sync()
    vfadam.sync()
    if rank == 0:
        print("Init param sum", th_init.sum(), flush=True)

    # Prepare for rollouts
    # ----------------------------------------
    seg_gen = traj_segment_generator(pi,
                                     env,
                                     reward_giver,
                                     timesteps_per_batch,
                                     stochastic=True)

    episodes_so_far = 0
    timesteps_so_far = 0
    iters_so_far = 0
    tstart = time.time()
    lenbuffer = deque(maxlen=40)  # rolling buffer for episode lengths
    rewbuffer = deque(maxlen=40)  # rolling buffer for episode rewards
    true_rewbuffer = deque(maxlen=40)

    assert sum([max_iters > 0, max_timesteps > 0, max_episodes > 0]) == 1

    g_loss_stats = stats(loss_names)
    d_loss_stats = stats(reward_giver.loss_name)
    ep_stats = stats(["True_rewards", "Rewards", "Episode_length"])
    # if provide pretrained weight
    if pretrained_weight is not None:
        U.load_state(pretrained_weight, var_list=pi.get_variables())

    while True:
        if callback: callback(locals(), globals())
        if max_timesteps and timesteps_so_far >= max_timesteps:
            break
        elif max_episodes and episodes_so_far >= max_episodes:
            break
        elif max_iters and iters_so_far >= max_iters:
            break

        # Save model
        if rank == 0 and iters_so_far % save_per_iter == 0 and ckpt_dir is not None:
            fname = os.path.join(ckpt_dir, task_name)
            os.makedirs(os.path.dirname(fname), exist_ok=True)
            saver = tf.train.Saver()
            saver.save(tf.get_default_session(), fname)

        logger.log("********** Iteration %i ************" % iters_so_far)

        def fisher_vector_product(p):
            return allmean(compute_fvp(p, *fvpargs)) + cg_damping * p

        # ------------------ Update G ------------------
        logger.log("Optimizing Policy...")
        for _ in range(g_step):
            with timed("sampling"):
                seg = seg_gen.__next__()
            add_vtarg_and_adv(seg, gamma, lam)
            # ob, ac, atarg, ret, td1ret = map(np.concatenate, (obs, acs, atargs, rets, td1rets))
            ob, ac, atarg, tdlamret = seg["ob"], seg["ac"], seg["adv"], seg[
                "tdlamret"]
            vpredbefore = seg[
                "vpred"]  # predicted value function before udpate
            atarg = (atarg - atarg.mean()) / atarg.std(
            )  # standardized advantage function estimate

            if hasattr(pi, "ob_rms"):
                pi.ob_rms.update(ob)  # update running mean/std for policy

            args = seg["ob"], seg["ac"], atarg
            fvpargs = [arr[::5] for arr in args]

            assign_old_eq_new(
            )  # set old parameter values to new parameter values
            with timed("computegrad"):
                *lossbefore, g = compute_lossandgrad(*args)
            lossbefore = allmean(np.array(lossbefore))
            g = allmean(g)
            if np.allclose(g, 0):
                logger.log("Got zero gradient. not updating")
            else:
                with timed("cg"):
                    stepdir = cg(fisher_vector_product,
                                 g,
                                 cg_iters=cg_iters,
                                 verbose=rank == 0)
                assert np.isfinite(stepdir).all()
                shs = .5 * stepdir.dot(fisher_vector_product(stepdir))
                lm = np.sqrt(shs / max_kl)
                # logger.log("lagrange multiplier:", lm, "gnorm:", np.linalg.norm(g))
                fullstep = stepdir / lm
                expectedimprove = g.dot(fullstep)
                surrbefore = lossbefore[0]
                stepsize = 1.0
                thbefore = get_flat()
                for _ in range(10):
                    thnew = thbefore + fullstep * stepsize
                    set_from_flat(thnew)
                    meanlosses = surr, kl, *_ = allmean(
                        np.array(compute_losses(*args)))
                    improve = surr - surrbefore
                    logger.log("Expected: %.3f Actual: %.3f" %
                               (expectedimprove, improve))
                    if not np.isfinite(meanlosses).all():
                        logger.log("Got non-finite value of losses -- bad!")
                    elif kl > max_kl * 1.5:
                        logger.log("violated KL constraint. shrinking step.")
                    elif improve < 0:
                        logger.log("surrogate didn't improve. shrinking step.")
                    else:
                        logger.log("Stepsize OK!")
                        break
                    stepsize *= .5
                else:
                    logger.log("couldn't compute a good step")
                    set_from_flat(thbefore)
                if nworkers > 1 and iters_so_far % 20 == 0:
                    paramsums = MPI.COMM_WORLD.allgather(
                        (thnew.sum(),
                         vfadam.getflat().sum()))  # list of tuples
                    assert all(
                        np.allclose(ps, paramsums[0]) for ps in paramsums[1:])
            with timed("vf"):
                for _ in range(vf_iters):
                    for (mbob, mbret) in dataset.iterbatches(
                        (seg["ob"], seg["tdlamret"]),
                            include_final_partial_batch=False,
                            batch_size=128):
                        if hasattr(pi, "ob_rms"):
                            pi.ob_rms.update(
                                mbob)  # update running mean/std for policy
                        g = allmean(compute_vflossandgrad(mbob, mbret))
                        vfadam.update(g, vf_stepsize)

        g_losses = meanlosses
        for (lossname, lossval) in zip(loss_names, meanlosses):
            logger.record_tabular(lossname, lossval)
        logger.record_tabular("ev_tdlam_before",
                              explained_variance(vpredbefore, tdlamret))
        # ------------------ Update D ------------------
        logger.log("Optimizing Discriminator...")
        logger.log(fmt_row(13, reward_giver.loss_name))
        ob_expert, ac_expert = expert_dataset.get_next_batch(len(ob))
        batch_size = len(ob) // d_step
        d_losses = [
        ]  # list of tuples, each of which gives the loss for a minibatch
        for ob_batch, ac_batch in dataset.iterbatches(
            (ob, ac), include_final_partial_batch=False,
                batch_size=batch_size):
            ob_expert, ac_expert = expert_dataset.get_next_batch(len(ob_batch))
            # update running mean/std for reward_giver
            if hasattr(reward_giver, "obs_rms"):
                reward_giver.obs_rms.update(
                    np.concatenate((ob_batch, ob_expert), 0))
            *newlosses, g = reward_giver.lossandgrad(ob_batch, ac_batch,
                                                     ob_expert, ac_expert)
            d_adam.update(allmean(g), d_stepsize)
            d_losses.append(newlosses)
        logger.log(fmt_row(13, np.mean(d_losses, axis=0)))

        lrlocal = (seg["ep_lens"], seg["ep_rets"], seg["ep_true_rets"]
                   )  # local values
        listoflrpairs = MPI.COMM_WORLD.allgather(lrlocal)  # list of tuples
        lens, rews, true_rets = map(flatten_lists, zip(*listoflrpairs))
        true_rewbuffer.extend(true_rets)
        lenbuffer.extend(lens)
        rewbuffer.extend(rews)

        logger.record_tabular("EpLenMean", np.mean(lenbuffer))
        logger.record_tabular("EpRewMean", np.mean(rewbuffer))
        logger.record_tabular("EpTrueRewMean", np.mean(true_rewbuffer))
        logger.record_tabular("EpThisIter", len(lens))
        episodes_so_far += len(lens)
        timesteps_so_far += sum(lens)
        iters_so_far += 1

        logger.record_tabular("EpisodesSoFar", episodes_so_far)
        logger.record_tabular("TimestepsSoFar", timesteps_so_far)
        logger.record_tabular("TimeElapsed", time.time() - tstart)

        if rank == 0:
            logger.dump_tabular()
def learn(env, policy_fn, *,
        timesteps_per_actorbatch, # timesteps per actor per update
        clip_param, entcoeff, # clipping parameter epsilon, entropy coeff
        optim_epochs, optim_stepsize, optim_batchsize,# optimization hypers
        gamma, lam, # advantage estimation
        max_timesteps=0, max_episodes=0, max_iters=0, max_seconds=0,  # time constraint
        callback=None, # you can do anything in the callback, since it takes locals(), globals()
        adam_epsilon=1e-5,
        schedule='constant' # annealing for stepsize parameters (epsilon and adam)
        ):
    # Setup losses and stuff
    # ----------------------------------------
    ob_space = env.observation_space
    ac_space = env.action_space
    pi = policy_fn("pi", ob_space, ac_space) # Construct network for new policy
    oldpi = policy_fn("oldpi", ob_space, ac_space) # Network for old policy
    atarg = tf.placeholder(dtype=tf.float32, shape=[None]) # Target advantage function (if applicable)
    ret = tf.placeholder(dtype=tf.float32, shape=[None]) # Empirical return

    lrmult = tf.placeholder(name='lrmult', dtype=tf.float32, shape=[]) # learning rate multiplier, updated with schedule

    ob = U.get_placeholder_cached(name="ob")
    ac = pi.pdtype.sample_placeholder([None])

    kloldnew = oldpi.pd.kl(pi.pd)
    ent = pi.pd.entropy()
    meankl = tf.reduce_mean(kloldnew)
    meanent = tf.reduce_mean(ent)
    pol_entpen = (-entcoeff) * meanent

    ratio = tf.exp(pi.pd.logp(ac) - oldpi.pd.logp(ac)) # pnew / pold
    surr1 = ratio * atarg # surrogate from conservative policy iteration
    surr2 = tf.clip_by_value(ratio, 1.0 - clip_param, 1.0 + clip_param) * atarg #
    pol_surr = - tf.reduce_mean(tf.minimum(surr1, surr2)) # PPO's pessimistic surrogate (L^CLIP)
    vf_loss = tf.reduce_mean(tf.square(pi.vpred - ret))
    total_loss = pol_surr + pol_entpen + vf_loss
    losses = [pol_surr, pol_entpen, vf_loss, meankl, meanent]
    loss_names = ["pol_surr", "pol_entpen", "vf_loss", "kl", "ent"]

    var_list = pi.get_trainable_variables()
    lossandgrad = U.function([ob, ac, atarg, ret, lrmult], losses + [U.flatgrad(total_loss, var_list)])
    adam = MpiAdam(var_list, epsilon=adam_epsilon)

    assign_old_eq_new = U.function([],[], updates=[tf.assign(oldv, newv)
        for (oldv, newv) in zipsame(oldpi.get_variables(), pi.get_variables())])
    compute_losses = U.function([ob, ac, atarg, ret, lrmult], losses)

    U.initialize()
    adam.sync()

    # Prepare for rollouts
    # ----------------------------------------
    seg_gen = traj_segment_generator(pi, env, timesteps_per_actorbatch, stochastic=True)

    episodes_so_far = 0
    timesteps_so_far = 0
    iters_so_far = 0
    tstart = time.time()
    lenbuffer = deque(maxlen=100) # rolling buffer for episode lengths
    rewbuffer = deque(maxlen=100) # rolling buffer for episode rewards

    assert sum([max_iters>0, max_timesteps>0, max_episodes>0, max_seconds>0])==1, "Only one time constraint permitted"

    while True:
        if callback: callback(locals(), globals())
        if max_timesteps and timesteps_so_far >= max_timesteps:
            break
        elif max_episodes and episodes_so_far >= max_episodes:
            break
        elif max_iters and iters_so_far >= max_iters:
            break
        elif max_seconds and time.time() - tstart >= max_seconds:
            break

        if schedule == 'constant':
            cur_lrmult = 1.0
        elif schedule == 'linear':
            cur_lrmult =  max(1.0 - float(timesteps_so_far) / max_timesteps, 0)
        else:
            raise NotImplementedError

        logger.log("********** Iteration %i ************"%iters_so_far)

        seg = seg_gen.__next__()
        add_vtarg_and_adv(seg, gamma, lam)

        # ob, ac, atarg, ret, td1ret = map(np.concatenate, (obs, acs, atargs, rets, td1rets))
        ob, ac, atarg, tdlamret = seg["ob"], seg["ac"], seg["adv"], seg["tdlamret"]
        vpredbefore = seg["vpred"] # predicted value function before udpate
        atarg = (atarg - atarg.mean()) / atarg.std() # standardized advantage function estimate
        d = Dataset(dict(ob=ob, ac=ac, atarg=atarg, vtarg=tdlamret), deterministic=pi.recurrent)
        optim_batchsize = optim_batchsize or ob.shape[0]

        if hasattr(pi, "ob_rms"): pi.ob_rms.update(ob) # update running mean/std for policy

        assign_old_eq_new() # set old parameter values to new parameter values
        logger.log("Optimizing...")
        logger.log(fmt_row(13, loss_names))
        # Here we do a bunch of optimization epochs over the data
        for _ in range(optim_epochs):
            losses = [] # list of tuples, each of which gives the loss for a minibatch
            for batch in d.iterate_once(optim_batchsize):
                *newlosses, g = lossandgrad(batch["ob"], batch["ac"], batch["atarg"], batch["vtarg"], cur_lrmult)
                adam.update(g, optim_stepsize * cur_lrmult)
                losses.append(newlosses)
            logger.log(fmt_row(13, np.mean(losses, axis=0)))

        logger.log("Evaluating losses...")
        losses = []
        for batch in d.iterate_once(optim_batchsize):
            newlosses = compute_losses(batch["ob"], batch["ac"], batch["atarg"], batch["vtarg"], cur_lrmult)
            losses.append(newlosses)
        meanlosses,_,_ = mpi_moments(losses, axis=0)
        logger.log(fmt_row(13, meanlosses))
        for (lossval, name) in zipsame(meanlosses, loss_names):
            logger.record_tabular("loss_"+name, lossval)
        logger.record_tabular("ev_tdlam_before", explained_variance(vpredbefore, tdlamret))
        lrlocal = (seg["ep_lens"], seg["ep_rets"]) # local values
        listoflrpairs = MPI.COMM_WORLD.allgather(lrlocal) # list of tuples
        lens, rews = map(flatten_lists, zip(*listoflrpairs))
        lenbuffer.extend(lens)
        rewbuffer.extend(rews)
        logger.record_tabular("EpLenMean", np.mean(lenbuffer))
        logger.record_tabular("EpRewMean", np.mean(rewbuffer))
        logger.record_tabular("EpThisIter", len(lens))
        episodes_so_far += len(lens)
        timesteps_so_far += sum(lens)
        iters_so_far += 1
        logger.record_tabular("EpisodesSoFar", episodes_so_far)
        logger.record_tabular("TimestepsSoFar", timesteps_so_far)
        logger.record_tabular("TimeElapsed", time.time() - tstart)
        if MPI.COMM_WORLD.Get_rank()==0:
            logger.dump_tabular()

    return pi
Exemple #3
0
def learn(*,
          network,
          env,
          total_timesteps,
          eval_env=None,
          seed=None,
          nsteps=128,
          ent_coef=0.0,
          lr=3e-4,
          vf_coef=0.5,
          max_grad_norm=0.5,
          gamma=0.99,
          lam=0.95,
          log_interval=10,
          nminibatches=1,
          noptepochs=4,
          cliprange=0.2,
          save_interval=10,
          load_path=None,
          model_fn=None,
          **network_kwargs):
    """
    Learn policy using PPO algorithm (https://arxiv.org/abs/1707.06347)

    Parameters:
    ----------

    network:                          policy network search_space. Either string (mlp, lstm, lnlstm, cnn_lstm, cnn, cnn_small, conv_only - see baselines.common/models.py for full list)
                                      specifying the standard network search_space, or a function that takes tensorflow tensor as input and returns
                                      tuple (output_tensor, extra_feed) where output tensor is the last network layer output, extra_feed is None for feed-forward
                                      neural nets, and extra_feed is a dictionary describing how to feed state into the network for recurrent neural nets.
                                      See common/models.py/lstm for more details on using recurrent nets in policies

    env: baselines.common.vec_env.VecEnv     environment. Needs to be vectorized for parallel environment simulation.
                                      The environments produced by gym.make can be wrapped using baselines.common.vec_env.DummyVecEnv class.


    nsteps: int                       number of steps of the vectorized environment per update (i.e. batch size is nsteps * nenv where
                                      nenv is number of environment copies simulated in parallel)

    total_timesteps: int              number of timesteps (i.e. number of actions taken in the environment)

    ent_coef: float                   policy entropy coefficient in the optimization objective

    lr: float or function             learning rate, constant or a schedule function [0,1] -> R+ where 1 is beginning of the
                                      training and 0 is the end of the training.

    vf_coef: float                    value function loss coefficient in the optimization objective

    max_grad_norm: float or None      gradient norm clipping coefficient

    gamma: float                      discounting factor for rewards

    lam: float                        advantage estimation discounting factor (lambda in the paper)

    log_interval: int                 number of timesteps between logging events

    nminibatches: int                 number of training minibatches per update. For recurrent policies,
                                      should be smaller or equal than number of environments run in parallel.

    noptepochs: int                   number of training epochs per update

    cliprange: float or function      clipping range, constant or schedule function [0,1] -> R+ where 1 is beginning of the training
                                      and 0 is the end of the training

    save_interval: int                number of timesteps between saving events

    load_path: str                    path to load the model from

    **network_kwargs:                 keyword arguments to the policy / network builder. See baselines.common/policies.py/build_policy and arguments to a particular type of network
                                      For instance, 'mlp' network search_space has arguments num_hidden and num_layers.
    """

    set_global_seeds(seed)

    if isinstance(lr, float):
        lr = constfn(lr)
    else:
        assert callable(lr)
    if isinstance(cliprange, float):
        cliprange = constfn(cliprange)
    else:
        assert callable(cliprange)
    #total_timesteps = int(total_timesteps)

    policy = build_ppo_policy(env, network, **network_kwargs)

    # Get the nb of env
    nenvs = env.num_envs

    # Get state_space and action_space
    ob_space = env.observation_space
    ac_space = env.action_space

    # Calculate the batch_size
    nbatch = nenvs * nsteps
    nbatch_train = nbatch // nminibatches

    # Instantiate the model object (that creates act_model and train_model)
    if model_fn is None:
        from deephyper.search.nas.baselines.ppo2.model import Model
        model_fn = Model

    model = model_fn(policy=policy,
                     ob_space=ob_space,
                     ac_space=ac_space,
                     nbatch_act=nenvs,
                     nbatch_train=nbatch_train,
                     nsteps=nsteps,
                     ent_coef=ent_coef,
                     vf_coef=vf_coef,
                     max_grad_norm=max_grad_norm)

    if load_path is not None:
        model.load(load_path)

    allvars = tf.get_collection(tf.GraphKeys.GLOBAL_VARIABLES,
                                scope=model.name)
    display_var_info(allvars)

    # Instantiate the runner object
    runner = Runner(env=env,
                    model=model,
                    nsteps=nsteps,
                    gamma=gamma,
                    ob_space=ob_space,
                    lam=lam)

    if eval_env is not None:
        eval_runner = Runner(env=eval_env,
                             model=model,
                             nsteps=nsteps,
                             gamma=gamma,
                             ob_space=ob_space,
                             lam=lam)

    epinfobuf = deque(maxlen=100)
    if eval_env is not None:
        eval_epinfobuf = deque(maxlen=100)

    # Start total timer
    tfirststart = time.perf_counter()
    nupdates = total_timesteps // nbatch

    # for update in range(1, nupdates + 1):
    update = 1
    while True:
        if not math.isnan(nupdates) and update >= nupdates:
            break
        assert nbatch % nminibatches == 0
        # Start timer
        tstart = time.perf_counter()
        frac = 1.0 - (update - 1.0) / nupdates
        # Calculate the learning rate
        lrnow = lr(frac)
        # Calculate the cliprange
        cliprangenow = cliprange(frac)

        # Get minibatch
        minibatch = runner.run()

        if eval_env is not None:
            eval_minibatch = eval_runner.run()
            _eval_obs = eval_minibatch['observations']  # noqa: F841
            _eval_returns = eval_minibatch['returns']  # noqa: F841
            _eval_masks = eval_minibatch['masks']  # noqa: F841
            _eval_actions = eval_minibatch['actions']  # noqa: F841
            _eval_values = eval_minibatch['values']  # noqa: F841
            _eval_neglogpacs = eval_minibatch['neglogpacs']  # noqa: F841
            _eval_states = eval_minibatch['state']  # noqa: F841
            eval_epinfos = eval_minibatch['epinfos']

        epinfobuf.extend(minibatch.pop('epinfos'))
        if eval_env is not None:
            eval_epinfobuf.extend(eval_epinfos)

        # Here what we're going to do is for each minibatch calculate the loss and append it.
        mblossvals = []

        # Index of each element of batch_size
        # Create the indices array
        inds = np.arange(nbatch)
        for _ in range(noptepochs):
            # Randomize the indexes
            np.random.shuffle(inds)
            # 0 to batch_size with batch_train_size step
            for start in range(0, nbatch, nbatch_train):
                end = start + nbatch_train
                mbinds = inds[start:end]
                slices = {key: minibatch[key][mbinds] for key in minibatch}
                mblossvals.append(model.train(lrnow, cliprangenow, **slices))

        # Feedforward --> get losses --> update
        lossvals = np.mean(mblossvals, axis=0)
        # End timer
        tnow = time.perf_counter()
        # Calculate the fps (frame per second)
        fps = int(nbatch / (tnow - tstart))
        if update % log_interval == 0 or update == 1:
            # Calculates if value function is a good predicator of the returns (ev > 1)
            # or if it's just worse than predicting nothing (ev =< 0)
            ev = explained_variance(minibatch['values'], minibatch['returns'])
            logger.logkv("serial_timesteps", update * nsteps)
            logger.logkv("nupdates", update)
            logger.logkv("total_timesteps", update * nbatch)
            logger.logkv("fps", fps)
            logger.logkv("explained_variance", float(ev))
            logger.logkv('eprewmean',
                         safemean([epinfo['r'] for epinfo in epinfobuf]))
            logger.logkv('eplenmean',
                         safemean([epinfo['l'] for epinfo in epinfobuf]))
            logger.logkv('rewards_per_step', safemean(minibatch['rewards']))
            logger.logkv('advantages_per_step', safemean(minibatch['advs']))

            if eval_env is not None:
                logger.logkv(
                    'eval_eprewmean',
                    safemean([epinfo['r'] for epinfo in eval_epinfobuf]))
                logger.logkv(
                    'eval_eplenmean',
                    safemean([epinfo['l'] for epinfo in eval_epinfobuf]))
            logger.logkv('time_elapsed', tnow - tfirststart)
            for (lossval, lossname) in zip(lossvals, model.loss_names):
                logger.logkv(lossname, lossval)
            if MPI is None or MPI.COMM_WORLD.Get_rank() == 0:
                logger.dumpkvs()
        if save_interval and (update % save_interval == 0
                              or update == 1) and logger.get_dir() and (
                                  MPI is None
                                  or MPI.COMM_WORLD.Get_rank() == 0):
            checkdir = osp.join(logger.get_dir(), 'checkpoints')
            os.makedirs(checkdir, exist_ok=True)
            savepath = osp.join(checkdir, '%.5i' % update)
            print('Saving to', savepath)
            model.save(savepath)
        del minibatch
        update += 1
    return model
Exemple #4
0
def learn(network,
          env,
          seed=None,
          nsteps=5,
          total_timesteps=int(80e6),
          vf_coef=0.5,
          ent_coef=0.01,
          max_grad_norm=0.5,
          lr=7e-4,
          lrschedule='linear',
          epsilon=1e-5,
          alpha=0.99,
          gamma=0.99,
          log_interval=100,
          load_path=None,
          **network_kwargs):
    '''
    Main entrypoint for A2C algorithm. Train a policy with given network search_space on a given environment using a2c algorithm.

    Parameters:
    -----------

    network:            policy network search_space. Either string (mlp, lstm, lnlstm, cnn_lstm, cnn, cnn_small, conv_only - see baselines.common/models.py for full list)
                        specifying the standard network search_space, or a function that takes tensorflow tensor as input and returns
                        tuple (output_tensor, extra_feed) where output tensor is the last network layer output, extra_feed is None for feed-forward
                        neural nets, and extra_feed is a dictionary describing how to feed state into the network for recurrent neural nets.
                        See baselines.common/policies.py/lstm for more details on using recurrent nets in policies


    env:                RL environment. Should implement interface similar to VecEnv (baselines.common/vec_env) or be wrapped with DummyVecEnv (baselines.common/vec_env/dummy_vec_env.py)


    seed:               seed to make random number sequence in the alorightm reproducible. By default is None which means seed from system noise generator (not reproducible)

    nsteps:             int, number of steps of the vectorized environment per update (i.e. batch size is nsteps * nenv where
                        nenv is number of environment copies simulated in parallel)

    total_timesteps:    int, total number of timesteps to train on (default: 80M)

    vf_coef:            float, coefficient in front of value function loss in the total loss function (default: 0.5)

    ent_coef:           float, coeffictiant in front of the policy entropy in the total loss function (default: 0.01)

    max_gradient_norm:  float, gradient is clipped to have global L2 norm no more than this value (default: 0.5)

    lr:                 float, learning rate for RMSProp (current implementation has RMSProp hardcoded in) (default: 7e-4)

    lrschedule:         schedule of learning rate. Can be 'linear', 'constant', or a function [0..1] -> [0..1] that takes fraction of the training progress as input and
                        returns fraction of the learning rate (specified as lr) as output

    epsilon:            float, RMSProp epsilon (stabilizes square root computation in denominator of RMSProp update) (default: 1e-5)

    alpha:              float, RMSProp decay parameter (default: 0.99)

    gamma:              float, reward discounting parameter (default: 0.99)

    log_interval:       int, specifies how frequently the logs are printed out (default: 100)

    **network_kwargs:   keyword arguments to the policy / network builder. See baselines.common/policies.py/build_policy and arguments to a particular type of network
                        For instance, 'mlp' network search_space has arguments num_hidden and num_layers.

    '''

    set_global_seeds(seed)

    # Get the nb of env
    nenvs = env.num_envs
    policy = build_policy(env, network, **network_kwargs)

    # Instantiate the model object (that creates step_model and train_model)
    model = Model(policy=policy,
                  env=env,
                  nsteps=nsteps,
                  ent_coef=ent_coef,
                  vf_coef=vf_coef,
                  max_grad_norm=max_grad_norm,
                  lr=lr,
                  alpha=alpha,
                  epsilon=epsilon,
                  total_timesteps=total_timesteps,
                  lrschedule=lrschedule)
    if load_path is not None:
        model.load(load_path)

    # Instantiate the runner object
    runner = Runner(env, model, nsteps=nsteps, gamma=gamma)
    epinfobuf = deque(maxlen=100)

    # Calculate the batch_size
    nbatch = nenvs * nsteps

    # Start total timer
    tstart = time.time()

    for update in range(1, total_timesteps // nbatch + 1):
        # Get mini batch of experiences
        obs, states, rewards, masks, actions, values, epinfos = runner.run()
        epinfobuf.extend(epinfos)

        policy_loss, value_loss, policy_entropy = model.train(
            obs, states, rewards, masks, actions, values)
        nseconds = time.time() - tstart

        # Calculate the fps (frame per second)
        fps = int((update * nbatch) / nseconds)
        if update % log_interval == 0 or update == 1:
            # Calculates if value function is a good predicator of the returns (ev > 1)
            # or if it's just worse than predicting nothing (ev =< 0)
            ev = explained_variance(values, rewards)
            logger.record_tabular("nupdates", update)
            logger.record_tabular("total_timesteps", update * nbatch)
            logger.record_tabular("fps", fps)
            logger.record_tabular("policy_entropy", float(policy_entropy))
            logger.record_tabular("value_loss", float(value_loss))
            logger.record_tabular("explained_variance", float(ev))
            logger.record_tabular(
                "eprewmean", safemean([epinfo['r'] for epinfo in epinfobuf]))
            logger.record_tabular(
                "eplenmean", safemean([epinfo['l'] for epinfo in epinfobuf]))
            logger.dump_tabular()
    return model
Exemple #5
0
def learn(
        *,
        network,
        env,
        total_timesteps,
        timesteps_per_batch=1024,  # what to train on
        max_kl=0.001,
        cg_iters=10,
        gamma=0.99,
        lam=1.0,  # advantage estimation
        seed=None,
        ent_coef=0.0,
        cg_damping=1e-2,
        vf_stepsize=3e-4,
        vf_iters=3,
        max_episodes=0,
        max_iters=0,  # time constraint
        callback=None,
        load_path=None,
        **network_kwargs):
    '''
    learn a policy function with TRPO algorithm

    Parameters:
    ----------

    network                 neural network to learn. Can be either string ('mlp', 'cnn', 'lstm', 'lnlstm' for basic types)
                            or function that takes input placeholder and returns tuple (output, None) for feedforward nets
                            or (output, (state_placeholder, state_output, mask_placeholder)) for recurrent nets

    env                     environment (one of the gym environments or wrapped via baselines.common.vec_env.VecEnv-type class

    timesteps_per_batch     timesteps per gradient estimation batch

    max_kl                  max KL divergence between old policy and new policy ( KL(pi_old || pi) )

    ent_coef                coefficient of policy entropy term in the optimization objective

    cg_iters                number of iterations of conjugate gradient algorithm

    cg_damping              conjugate gradient damping

    vf_stepsize             learning rate for adam optimizer used to optimie value function loss

    vf_iters                number of iterations of value function optimization iterations per each policy optimization step

    total_timesteps           max number of timesteps

    max_episodes            max number of episodes

    max_iters               maximum number of policy optimization iterations

    callback                function to be called with (locals(), globals()) each policy optimization step

    load_path               str, path to load the model from (default: None, i.e. no model is loaded)

    **network_kwargs        keyword arguments to the policy / network builder. See baselines.common/policies.py/build_policy and arguments to a particular type of network

    Returns:
    -------

    learnt model

    '''

    if MPI is not None:
        nworkers = MPI.COMM_WORLD.Get_size()
        rank = MPI.COMM_WORLD.Get_rank()
    else:
        nworkers = 1
        rank = 0

    cpus_per_worker = 1
    U.get_session(
        config=tf.ConfigProto(allow_soft_placement=True,
                              inter_op_parallelism_threads=cpus_per_worker,
                              intra_op_parallelism_threads=cpus_per_worker))

    policy = build_policy(env, network, value_network='copy', **network_kwargs)
    set_global_seeds(seed)

    np.set_printoptions(precision=3)
    # Setup losses and stuff
    # ----------------------------------------
    ob_space = env.observation_space
    ac_space = env.action_space

    ob = observation_placeholder(ob_space)
    with tf.variable_scope("pi"):
        pi = policy(observ_placeholder=ob)
    with tf.variable_scope("oldpi"):
        oldpi = policy(observ_placeholder=ob)

    atarg = tf.placeholder(
        dtype=tf.float32,
        shape=[None])  # Target advantage function (if applicable)
    ret = tf.placeholder(dtype=tf.float32, shape=[None])  # Empirical return

    ac = pi.pdtype.sample_placeholder([None])

    kloldnew = oldpi.pd.kl(pi.pd)
    ent = pi.pd.entropy()
    meankl = tf.reduce_mean(kloldnew)
    meanent = tf.reduce_mean(ent)
    entbonus = ent_coef * meanent

    vferr = tf.reduce_mean(tf.square(pi.vf - ret))

    ratio = tf.exp(pi.pd.logp(ac) -
                   oldpi.pd.logp(ac))  # advantage * pnew / pold
    surrgain = tf.reduce_mean(ratio * atarg)

    optimgain = surrgain + entbonus
    losses = [optimgain, meankl, entbonus, surrgain, meanent]
    loss_names = ["optimgain", "meankl", "entloss", "surrgain", "entropy"]

    dist = meankl

    all_var_list = get_trainable_variables("pi")
    # var_list = [v for v in all_var_list if v.name.split("/")[1].startswith("pol")]
    # vf_var_list = [v for v in all_var_list if v.name.split("/")[1].startswith("vf")]
    var_list = get_pi_trainable_variables("pi")
    vf_var_list = get_vf_trainable_variables("pi")

    vfadam = MpiAdam(vf_var_list)

    get_flat = U.GetFlat(var_list)
    set_from_flat = U.SetFromFlat(var_list)
    klgrads = tf.gradients(dist, var_list)
    flat_tangent = tf.placeholder(dtype=tf.float32,
                                  shape=[None],
                                  name="flat_tan")
    shapes = [var.get_shape().as_list() for var in var_list]
    start = 0
    tangents = []
    for shape in shapes:
        sz = U.intprod(shape)
        tangents.append(tf.reshape(flat_tangent[start:start + sz], shape))
        start += sz
    gvp = tf.add_n([
        tf.reduce_sum(g * tangent)
        for (g, tangent) in zipsame(klgrads, tangents)
    ])  #pylint: disable=E1111
    fvp = U.flatgrad(gvp, var_list)

    assign_old_eq_new = U.function(
        [], [],
        updates=[
            tf.assign(oldv, newv)
            for (oldv,
                 newv) in zipsame(get_variables("oldpi"), get_variables("pi"))
        ])

    compute_losses = U.function([ob, ac, atarg], losses)
    compute_lossandgrad = U.function([ob, ac, atarg], losses +
                                     [U.flatgrad(optimgain, var_list)])
    compute_fvp = U.function([flat_tangent, ob, ac, atarg], fvp)
    compute_vflossandgrad = U.function([ob, ret],
                                       U.flatgrad(vferr, vf_var_list))

    @contextmanager
    def timed(msg):
        if rank == 0:
            print(colorize(msg, color='magenta'))
            tstart = time.time()
            yield
            print(
                colorize("done in %.3f seconds" % (time.time() - tstart),
                         color='magenta'))
        else:
            yield

    def allmean(x):
        assert isinstance(x, np.ndarray)
        if MPI is not None:
            out = np.empty_like(x)
            MPI.COMM_WORLD.Allreduce(x, out, op=MPI.SUM)
            out /= nworkers
        else:
            out = np.copy(x)

        return out

    U.initialize()
    if load_path is not None:
        pi.load(load_path)

    th_init = get_flat()
    if MPI is not None:
        MPI.COMM_WORLD.Bcast(th_init, root=0)

    set_from_flat(th_init)
    vfadam.sync()
    print("Init param sum", th_init.sum(), flush=True)

    # Prepare for rollouts
    # ----------------------------------------
    seg_gen = traj_segment_generator(pi,
                                     env,
                                     timesteps_per_batch,
                                     stochastic=True)

    episodes_so_far = 0
    timesteps_so_far = 0
    iters_so_far = 0
    tstart = time.time()
    lenbuffer = deque(maxlen=40)  # rolling buffer for episode lengths
    rewbuffer = deque(maxlen=40)  # rolling buffer for episode rewards

    if sum([max_iters > 0, total_timesteps > 0, max_episodes > 0]) == 0:
        # noththing to be done
        return pi

    assert sum([max_iters>0, total_timesteps>0, max_episodes>0]) < 2, \
        'out of max_iters, total_timesteps, and max_episodes only one should be specified'

    while True:
        if callback: callback(locals(), globals())
        if total_timesteps and timesteps_so_far >= total_timesteps:
            break
        elif max_episodes and episodes_so_far >= max_episodes:
            break
        elif max_iters and iters_so_far >= max_iters:
            break
        logger.log("********** Iteration %i ************" % iters_so_far)

        with timed("sampling"):
            seg = seg_gen.__next__()
        add_vtarg_and_adv(seg, gamma, lam)

        # ob, ac, atarg, ret, td1ret = map(np.concatenate, (obs, acs, atargs, rets, td1rets))
        ob, ac, atarg, tdlamret = seg["ob"], seg["ac"], seg["adv"], seg[
            "tdlamret"]
        vpredbefore = seg["vpred"]  # predicted value function before udpate
        atarg = (atarg - atarg.mean()
                 ) / atarg.std()  # standardized advantage function estimate

        if hasattr(pi, "ret_rms"): pi.ret_rms.update(tdlamret)
        if hasattr(pi, "ob_rms"):
            pi.ob_rms.update(ob)  # update running mean/std for policy

        args = seg["ob"], seg["ac"], atarg
        fvpargs = [arr[::5] for arr in args]

        def fisher_vector_product(p):
            return allmean(compute_fvp(p, *fvpargs)) + cg_damping * p

        assign_old_eq_new()  # set old parameter values to new parameter values
        with timed("computegrad"):
            *lossbefore, g = compute_lossandgrad(*args)
        lossbefore = allmean(np.array(lossbefore))
        g = allmean(g)
        if np.allclose(g, 0):
            logger.log("Got zero gradient. not updating")
        else:
            with timed("cg"):
                stepdir = cg(fisher_vector_product,
                             g,
                             cg_iters=cg_iters,
                             verbose=rank == 0)
            assert np.isfinite(stepdir).all()
            shs = .5 * stepdir.dot(fisher_vector_product(stepdir))
            lm = np.sqrt(shs / max_kl)
            # logger.log("lagrange multiplier:", lm, "gnorm:", np.linalg.norm(g))
            fullstep = stepdir / lm
            expectedimprove = g.dot(fullstep)
            surrbefore = lossbefore[0]
            stepsize = 1.0
            thbefore = get_flat()
            for _ in range(10):
                thnew = thbefore + fullstep * stepsize
                set_from_flat(thnew)
                meanlosses = surr, kl, *_ = allmean(
                    np.array(compute_losses(*args)))
                improve = surr - surrbefore
                logger.log("Expected: %.3f Actual: %.3f" %
                           (expectedimprove, improve))
                if not np.isfinite(meanlosses).all():
                    logger.log("Got non-finite value of losses -- bad!")
                elif kl > max_kl * 1.5:
                    logger.log("violated KL constraint. shrinking step.")
                elif improve < 0:
                    logger.log("surrogate didn't improve. shrinking step.")
                else:
                    logger.log("Stepsize OK!")
                    break
                stepsize *= .5
            else:
                logger.log("couldn't compute a good step")
                set_from_flat(thbefore)
            if nworkers > 1 and iters_so_far % 20 == 0:
                paramsums = MPI.COMM_WORLD.allgather(
                    (thnew.sum(), vfadam.getflat().sum()))  # list of tuples
                assert all(
                    np.allclose(ps, paramsums[0]) for ps in paramsums[1:])

        for (lossname, lossval) in zip(loss_names, meanlosses):
            logger.record_tabular(lossname, lossval)

        with timed("vf"):

            for _ in range(vf_iters):
                for (mbob, mbret) in dataset.iterbatches(
                    (seg["ob"], seg["tdlamret"]),
                        include_final_partial_batch=False,
                        batch_size=64):
                    g = allmean(compute_vflossandgrad(mbob, mbret))
                    vfadam.update(g, vf_stepsize)

        logger.record_tabular("ev_tdlam_before",
                              explained_variance(vpredbefore, tdlamret))

        lrlocal = (seg["ep_lens"], seg["ep_rets"])  # local values
        if MPI is not None:
            listoflrpairs = MPI.COMM_WORLD.allgather(lrlocal)  # list of tuples
        else:
            listoflrpairs = [lrlocal]

        lens, rews = map(flatten_lists, zip(*listoflrpairs))
        lenbuffer.extend(lens)
        rewbuffer.extend(rews)

        logger.record_tabular("EpLenMean", np.mean(lenbuffer))
        logger.record_tabular("EpRewMean", np.mean(rewbuffer))
        logger.record_tabular("EpThisIter", len(lens))
        episodes_so_far += len(lens)
        timesteps_so_far += sum(lens)
        iters_so_far += 1

        logger.record_tabular("EpisodesSoFar", episodes_so_far)
        logger.record_tabular("TimestepsSoFar", timesteps_so_far)
        logger.record_tabular("TimeElapsed", time.time() - tstart)

        if rank == 0:
            logger.dump_tabular()

    return pi
Exemple #6
0
def learn(network,
          env,
          seed,
          total_timesteps=int(40e6),
          gamma=0.99,
          log_interval=1,
          nprocs=32,
          nsteps=20,
          ent_coef=0.01,
          vf_coef=0.5,
          vf_fisher_coef=1.0,
          lr=0.25,
          max_grad_norm=0.5,
          kfac_clip=0.001,
          save_interval=None,
          lrschedule='linear',
          load_path=None,
          is_async=True,
          **network_kwargs):
    set_global_seeds(seed)

    if network == 'cnn':
        network_kwargs['one_dim_bias'] = True

    policy = build_policy(env, network, **network_kwargs)

    nenvs = env.num_envs
    ob_space = env.observation_space
    ac_space = env.action_space
    make_model = lambda: Model(policy,
                               ob_space,
                               ac_space,
                               nenvs,
                               total_timesteps,
                               nprocs=nprocs,
                               nsteps=nsteps,
                               ent_coef=ent_coef,
                               vf_coef=vf_coef,
                               vf_fisher_coef=vf_fisher_coef,
                               lr=lr,
                               max_grad_norm=max_grad_norm,
                               kfac_clip=kfac_clip,
                               lrschedule=lrschedule,
                               is_async=is_async)
    if save_interval and logger.get_dir():
        import cloudpickle
        with open(osp.join(logger.get_dir(), 'make_model.pkl'), 'wb') as fh:
            fh.write(cloudpickle.dumps(make_model))
    model = make_model()

    if load_path is not None:
        model.load(load_path)

    runner = Runner(env, model, nsteps=nsteps, gamma=gamma)
    epinfobuf = deque(maxlen=100)
    nbatch = nenvs * nsteps
    tstart = time.time()
    coord = tf.train.Coordinator()
    if is_async:
        enqueue_threads = model.q_runner.create_threads(model.sess,
                                                        coord=coord,
                                                        start=True)
    else:
        enqueue_threads = []

    for update in range(1, total_timesteps // nbatch + 1):
        obs, states, rewards, masks, actions, values, epinfos = runner.run()
        epinfobuf.extend(epinfos)
        policy_loss, value_loss, policy_entropy = model.train(
            obs, states, rewards, masks, actions, values)
        model.old_obs = obs
        nseconds = time.time() - tstart
        fps = int((update * nbatch) / nseconds)
        if update % log_interval == 0 or update == 1:
            ev = explained_variance(values, rewards)
            logger.record_tabular("nupdates", update)
            logger.record_tabular("total_timesteps", update * nbatch)
            logger.record_tabular("fps", fps)
            logger.record_tabular("policy_entropy", float(policy_entropy))
            logger.record_tabular("policy_loss", float(policy_loss))
            logger.record_tabular("value_loss", float(value_loss))
            logger.record_tabular("explained_variance", float(ev))
            logger.record_tabular(
                "eprewmean", safemean([epinfo['r'] for epinfo in epinfobuf]))
            logger.record_tabular(
                "eplenmean", safemean([epinfo['l'] for epinfo in epinfobuf]))
            logger.dump_tabular()

        if save_interval and (update % save_interval == 0
                              or update == 1) and logger.get_dir():
            savepath = osp.join(logger.get_dir(), 'checkpoint%.5i' % update)
            print('Saving to', savepath)
            model.save(savepath)
    coord.request_stop()
    coord.join(enqueue_threads)
    return model