feat: add pusht image imf transformer

2026-03-26 20:41:37 +08:00
parent 5e7ae6cfa5
commit 4cd5085b33
5 changed files with 960 additions and 0 deletions
--- a/diffusion_policy/model/diffusion/imf_transformer_for_diffusion.py
+++ b/diffusion_policy/model/diffusion/imf_transformer_for_diffusion.py
@@ -0,0 +1,298 @@
 from typing import Optional, Tuple, Union
 import logging
 import torch
 import torch.nn as nn
 from diffusion_policy.model.common.module_attr_mixin import ModuleAttrMixin
 from diffusion_policy.model.diffusion.positional_embedding import SinusoidalPosEmb
 logger = logging.getLogger(__name__)
 class IMFTransformerForDiffusion(ModuleAttrMixin):
    def __init__(
        self,
        input_dim: int,
        output_dim: int,
        horizon: int,
        n_obs_steps: int = None,
        cond_dim: int = 0,
        n_layer: int = 12,
        n_head: int = 1,
        n_emb: int = 768,
        p_drop_emb: float = 0.1,
        p_drop_attn: float = 0.1,
        causal_attn: bool = False,
        time_as_cond: bool = True,
        obs_as_cond: bool = False,
        n_cond_layers: int = 0,
    ) -> None:
        super().__init__()
        assert n_head == 1, 'IMFTransformerForDiffusion currently supports single-head attention only.'
        if n_obs_steps is None:
            n_obs_steps = horizon
        T = horizon
        T_cond = 2
        if not time_as_cond:
            T += 2
            T_cond -= 2
        obs_as_cond = cond_dim > 0
        if obs_as_cond:
            assert time_as_cond
            T_cond += n_obs_steps
        self.input_emb = nn.Linear(input_dim, n_emb)
        self.pos_emb = nn.Parameter(torch.zeros(1, T, n_emb))
        self.drop = nn.Dropout(p_drop_emb)
        self.time_emb = SinusoidalPosEmb(n_emb)
        self.cond_obs_emb = None
        if obs_as_cond:
            self.cond_obs_emb = nn.Linear(cond_dim, n_emb)
        self.cond_pos_emb = None
        self.encoder = None
        self.decoder = None
        encoder_only = False
        if T_cond > 0:
            self.cond_pos_emb = nn.Parameter(torch.zeros(1, T_cond, n_emb))
            if n_cond_layers > 0:
                encoder_layer = nn.TransformerEncoderLayer(
                    d_model=n_emb,
                    nhead=n_head,
                    dim_feedforward=4 * n_emb,
                    dropout=p_drop_attn,
                    activation='gelu',
                    batch_first=True,
                    norm_first=True,
                )
                self.encoder = nn.TransformerEncoder(
                    encoder_layer=encoder_layer,
                    num_layers=n_cond_layers,
                )
            else:
                self.encoder = nn.Sequential(
                    nn.Linear(n_emb, 4 * n_emb),
                    nn.Mish(),
                    nn.Linear(4 * n_emb, n_emb),
                )
            decoder_layer = nn.TransformerDecoderLayer(
                d_model=n_emb,
                nhead=n_head,
                dim_feedforward=4 * n_emb,
                dropout=p_drop_attn,
                activation='gelu',
                batch_first=True,
                norm_first=True,
            )
            self.decoder = nn.TransformerDecoder(
                decoder_layer=decoder_layer,
                num_layers=n_layer,
            )
        else:
            encoder_only = True
            encoder_layer = nn.TransformerEncoderLayer(
                d_model=n_emb,
                nhead=n_head,
                dim_feedforward=4 * n_emb,
                dropout=p_drop_attn,
                activation='gelu',
                batch_first=True,
                norm_first=True,
            )
            self.encoder = nn.TransformerEncoder(
                encoder_layer=encoder_layer,
                num_layers=n_layer,
            )
        if causal_attn:
            sz = T
            mask = (torch.triu(torch.ones(sz, sz)) == 1).transpose(0, 1)
            mask = mask.float().masked_fill(mask == 0, float('-inf')).masked_fill(mask == 1, float(0.0))
            self.register_buffer('mask', mask)
            if time_as_cond and obs_as_cond:
                S = T_cond
                t_idx, s_idx = torch.meshgrid(
                    torch.arange(T),
                    torch.arange(S),
                    indexing='ij',
                )
                mask = t_idx >= (s_idx - 2)
                mask = mask.float().masked_fill(mask == 0, float('-inf')).masked_fill(mask == 1, float(0.0))
                self.register_buffer('memory_mask', mask)
            else:
                self.memory_mask = None
        else:
            self.mask = None
            self.memory_mask = None
        self.ln_f = nn.LayerNorm(n_emb)
        self.head = nn.Linear(n_emb, output_dim)
        self.T = T
        self.T_cond = T_cond
        self.horizon = horizon
        self.time_as_cond = time_as_cond
        self.obs_as_cond = obs_as_cond
        self.encoder_only = encoder_only
        self.apply(self._init_weights)
        logger.info(
            'number of parameters: %e',
            sum(p.numel() for p in self.parameters()),
        )
    def _init_weights(self, module):
        ignore_types = (
            nn.Dropout,
            SinusoidalPosEmb,
            nn.TransformerEncoderLayer,
            nn.TransformerDecoderLayer,
            nn.TransformerEncoder,
            nn.TransformerDecoder,
            nn.ModuleList,
            nn.Mish,
            nn.Sequential,
        )
        if isinstance(module, (nn.Linear, nn.Embedding)):
            torch.nn.init.normal_(module.weight, mean=0.0, std=0.02)
            if isinstance(module, nn.Linear) and module.bias is not None:
                torch.nn.init.zeros_(module.bias)
        elif isinstance(module, nn.MultiheadAttention):
            weight_names = ['in_proj_weight', 'q_proj_weight', 'k_proj_weight', 'v_proj_weight']
            for name in weight_names:
                weight = getattr(module, name)
                if weight is not None:
                    torch.nn.init.normal_(weight, mean=0.0, std=0.02)
            bias_names = ['in_proj_bias', 'bias_k', 'bias_v']
            for name in bias_names:
                bias = getattr(module, name)
                if bias is not None:
                    torch.nn.init.zeros_(bias)
        elif isinstance(module, nn.LayerNorm):
            torch.nn.init.zeros_(module.bias)
            torch.nn.init.ones_(module.weight)
        elif isinstance(module, IMFTransformerForDiffusion):
            torch.nn.init.normal_(module.pos_emb, mean=0.0, std=0.02)
            if module.cond_obs_emb is not None:
                torch.nn.init.normal_(module.cond_pos_emb, mean=0.0, std=0.02)
        elif isinstance(module, ignore_types):
            pass
        else:
            raise RuntimeError(f'Unaccounted module {module}')
    def get_optim_groups(self, weight_decay: float = 1e-3):
        decay = set()
        no_decay = set()
        whitelist_weight_modules = (torch.nn.Linear, torch.nn.MultiheadAttention)
        blacklist_weight_modules = (torch.nn.LayerNorm, torch.nn.Embedding)
        for mn, m in self.named_modules():
            for pn, _ in m.named_parameters():
                fpn = '%s.%s' % (mn, pn) if mn else pn
                if pn.endswith('bias'):
                    no_decay.add(fpn)
                elif pn.startswith('bias'):
                    no_decay.add(fpn)
                elif pn.endswith('weight') and isinstance(m, whitelist_weight_modules):
                    decay.add(fpn)
                elif pn.endswith('weight') and isinstance(m, blacklist_weight_modules):
                    no_decay.add(fpn)
        no_decay.add('pos_emb')
        no_decay.add('_dummy_variable')
        if self.cond_pos_emb is not None:
            no_decay.add('cond_pos_emb')
        param_dict = {pn: p for pn, p in self.named_parameters()}
        inter_params = decay & no_decay
        union_params = decay | no_decay
        assert len(inter_params) == 0, f'parameters {inter_params} made it into both decay/no_decay sets!'
        assert len(param_dict.keys() - union_params) == 0, (
            f'parameters {param_dict.keys() - union_params} were not separated into either decay/no_decay sets!'
        )
        optim_groups = [
            {
                'params': [param_dict[pn] for pn in sorted(list(decay))],
                'weight_decay': weight_decay,
            },
            {
                'params': [param_dict[pn] for pn in sorted(list(no_decay))],
                'weight_decay': 0.0,
            },
        ]
        return optim_groups
    def configure_optimizers(
        self,
        learning_rate: float = 1e-4,
        weight_decay: float = 1e-3,
        betas: Tuple[float, float] = (0.9, 0.95),
    ):
        optim_groups = self.get_optim_groups(weight_decay=weight_decay)
        optimizer = torch.optim.AdamW(optim_groups, lr=learning_rate, betas=betas)
        return optimizer
    def _prepare_time_input(self, value: Union[torch.Tensor, float, int], sample: torch.Tensor) -> torch.Tensor:
        if not torch.is_tensor(value):
            value = torch.tensor([value], dtype=sample.dtype, device=sample.device)
        elif value.ndim == 0:
            value = value[None].to(device=sample.device, dtype=sample.dtype)
        else:
            value = value.to(device=sample.device, dtype=sample.dtype)
        return value.expand(sample.shape[0])
    def forward(
        self,
        sample: torch.Tensor,
        r: Union[torch.Tensor, float, int],
        t: Union[torch.Tensor, float, int],
        cond: Optional[torch.Tensor] = None,
    ):
        r = self._prepare_time_input(r, sample)
        t = self._prepare_time_input(t, sample)
        r_emb = self.time_emb(r).unsqueeze(1)
        t_emb = self.time_emb(t).unsqueeze(1)
        input_emb = self.input_emb(sample)
        if self.encoder_only:
            token_embeddings = torch.cat([r_emb, t_emb, input_emb], dim=1)
            token_count = token_embeddings.shape[1]
            position_embeddings = self.pos_emb[:, :token_count, :]
            x = self.drop(token_embeddings + position_embeddings)
            x = self.encoder(src=x, mask=self.mask)
            x = x[:, 2:, :]
        else:
            cond_embeddings = torch.cat([r_emb, t_emb], dim=1)
            if self.obs_as_cond:
                cond_obs_emb = self.cond_obs_emb(cond)
                cond_embeddings = torch.cat([cond_embeddings, cond_obs_emb], dim=1)
            token_count = cond_embeddings.shape[1]
            position_embeddings = self.cond_pos_emb[:, :token_count, :]
            x = self.drop(cond_embeddings + position_embeddings)
            x = self.encoder(x)
            memory = x
            token_embeddings = input_emb
            token_count = token_embeddings.shape[1]
            position_embeddings = self.pos_emb[:, :token_count, :]
            x = self.drop(token_embeddings + position_embeddings)
            x = self.decoder(
                tgt=x,
                memory=memory,
                tgt_mask=self.mask,
                memory_mask=self.memory_mask,
            )
        x = self.ln_f(x)
        x = self.head(x)
        return x
--- a/diffusion_policy/policy/imf_transformer_hybrid_image_policy.py
+++ b/diffusion_policy/policy/imf_transformer_hybrid_image_policy.py
@@ -0,0 +1,273 @@
 from contextlib import nullcontext
 from typing import Dict, Optional
 import torch
 import torch.nn.functional as F
 from einops import reduce
 from diffusion_policy.common.pytorch_util import dict_apply
 from diffusion_policy.model.diffusion.imf_transformer_for_diffusion import IMFTransformerForDiffusion
 from diffusion_policy.policy.diffusion_transformer_hybrid_image_policy import (
    DiffusionTransformerHybridImagePolicy,
 )
 try:
    from torch.func import jvp as TORCH_FUNC_JVP
 except ImportError:  # pragma: no cover - depends on torch version
    TORCH_FUNC_JVP = None
 class IMFTransformerHybridImagePolicy(DiffusionTransformerHybridImagePolicy):
    def __init__(
        self,
        shape_meta: dict,
        noise_scheduler,
        horizon,
        n_action_steps,
        n_obs_steps,
        num_inference_steps=None,
        crop_shape=(76, 76),
        obs_encoder_group_norm=False,
        eval_fixed_crop=False,
        n_layer=8,
        n_cond_layers=0,
        n_head=1,
        n_emb=256,
        p_drop_emb=0.0,
        p_drop_attn=0.3,
        causal_attn=True,
        time_as_cond=True,
        obs_as_cond=True,
        pred_action_steps_only=False,
        **kwargs,
    ):
        if num_inference_steps is None:
            num_inference_steps = 1
        elif num_inference_steps != 1:
            raise ValueError(
                'IMFTransformerHybridImagePolicy only supports one-step inference; '
                f'num_inference_steps must be 1, got {num_inference_steps}.'
            )
        super().__init__(
            shape_meta=shape_meta,
            noise_scheduler=noise_scheduler,
            horizon=horizon,
            n_action_steps=n_action_steps,
            n_obs_steps=n_obs_steps,
            num_inference_steps=num_inference_steps,
            crop_shape=crop_shape,
            obs_encoder_group_norm=obs_encoder_group_norm,
            eval_fixed_crop=eval_fixed_crop,
            n_layer=n_layer,
            n_cond_layers=n_cond_layers,
            n_head=n_head,
            n_emb=n_emb,
            p_drop_emb=p_drop_emb,
            p_drop_attn=p_drop_attn,
            causal_attn=causal_attn,
            time_as_cond=time_as_cond,
            obs_as_cond=obs_as_cond,
            pred_action_steps_only=pred_action_steps_only,
            **kwargs,
        )
        input_dim = self.action_dim if self.obs_as_cond else (self.obs_feature_dim + self.action_dim)
        cond_dim = self.obs_feature_dim if self.obs_as_cond else 0
        model_horizon = self.n_action_steps if self.pred_action_steps_only else horizon
        self.model = IMFTransformerForDiffusion(
            input_dim=input_dim,
            output_dim=input_dim,
            horizon=model_horizon,
            n_obs_steps=n_obs_steps,
            cond_dim=cond_dim,
            n_layer=n_layer,
            n_head=n_head,
            n_emb=n_emb,
            p_drop_emb=p_drop_emb,
            p_drop_attn=p_drop_attn,
            causal_attn=causal_attn,
            time_as_cond=time_as_cond,
            obs_as_cond=obs_as_cond,
            n_cond_layers=n_cond_layers,
        )
        self.num_inference_steps = 1
    def fn(self, z: torch.Tensor, r: torch.Tensor, t: torch.Tensor, cond=None) -> torch.Tensor:
        return self.model(z, r, t, cond=cond)
    @staticmethod
    def _broadcast_batch_time(value: torch.Tensor, reference: torch.Tensor) -> torch.Tensor:
        while value.ndim < reference.ndim:
            value = value.unsqueeze(-1)
        return value
    @staticmethod
    def _apply_conditioning(
        trajectory: torch.Tensor,
        condition_data: Optional[torch.Tensor] = None,
        condition_mask: Optional[torch.Tensor] = None,
    ) -> torch.Tensor:
        if condition_data is None or condition_mask is None:
            return trajectory
        conditioned = trajectory.clone()
        conditioned[condition_mask] = condition_data[condition_mask]
        return conditioned
    @staticmethod
    def _jvp_math_sdp_context(z_t: torch.Tensor):
        if z_t.is_cuda:
            return torch.backends.cuda.sdp_kernel(
                enable_flash=False,
                enable_math=True,
                enable_mem_efficient=False,
                enable_cudnn=False,
            )
        return nullcontext()
    @staticmethod
    def _jvp_tangents(v: torch.Tensor, r: torch.Tensor, t: torch.Tensor):
        return v.detach(), torch.zeros_like(r), torch.ones_like(t)
    def _compute_u_and_du_dt(
        self,
        z_t: torch.Tensor,
        r: torch.Tensor,
        t: torch.Tensor,
        cond,
        v: torch.Tensor,
        condition_data: Optional[torch.Tensor] = None,
        condition_mask: Optional[torch.Tensor] = None,
    ):
        tangents = self._jvp_tangents(v, r, t)
        def g(z, r_value, t_value):
            conditioned_z = self._apply_conditioning(z, condition_data, condition_mask)
            return self.fn(conditioned_z, r_value, t_value, cond=cond)
        with self._jvp_math_sdp_context(z_t):
            if TORCH_FUNC_JVP is not None:
                try:
                    return TORCH_FUNC_JVP(g, (z_t, r, t), tangents)
                except (RuntimeError, TypeError, NotImplementedError):
                    pass
            u = g(z_t, r, t)
            _, du_dt = torch.autograd.functional.jvp(
                g,
                (z_t, r, t),
                tangents,
                create_graph=False,
                strict=False,
            )
        return u, du_dt
    def _compound_velocity(
        self,
        u: torch.Tensor,
        du_dt: torch.Tensor,
        r: torch.Tensor,
        t: torch.Tensor,
    ) -> torch.Tensor:
        delta = self._broadcast_batch_time(t - r, u)
        return u + delta * du_dt.detach()
    def _sample_one_step(
        self,
        z_t: torch.Tensor,
        r: torch.Tensor = None,
        t: torch.Tensor = None,
        cond=None,
    ) -> torch.Tensor:
        batch_size = z_t.shape[0]
        if t is None:
            t = torch.ones(batch_size, device=z_t.device, dtype=z_t.dtype)
        if r is None:
            r = torch.zeros(batch_size, device=z_t.device, dtype=z_t.dtype)
        u = self.fn(z_t, r, t, cond=cond)
        delta = self._broadcast_batch_time(t - r, z_t)
        return z_t - delta * u
    def conditional_sample(
        self,
        condition_data,
        condition_mask,
        cond=None,
        generator=None,
        **kwargs,
    ):
        trajectory = torch.randn(
            size=condition_data.shape,
            dtype=condition_data.dtype,
            device=condition_data.device,
            generator=generator,
        )
        trajectory = self._apply_conditioning(trajectory, condition_data, condition_mask)
        trajectory = self._sample_one_step(trajectory, cond=cond)
        trajectory = self._apply_conditioning(trajectory, condition_data, condition_mask)
        return trajectory
    def compute_loss(self, batch):
        assert 'valid_mask' not in batch
        nobs = self.normalizer.normalize(batch['obs'])
        nactions = self.normalizer['action'].normalize(batch['action'])
        batch_size = nactions.shape[0]
        horizon = nactions.shape[1]
        To = self.n_obs_steps
        cond = None
        trajectory = nactions
        if self.obs_as_cond:
            this_nobs = dict_apply(
                nobs,
                lambda x: x[:, :To, ...].reshape(-1, *x.shape[2:]),
            )
            nobs_features = self.obs_encoder(this_nobs)
            cond = nobs_features.reshape(batch_size, To, -1)
            if self.pred_action_steps_only:
                start = To - 1
                end = start + self.n_action_steps
                trajectory = nactions[:, start:end]
        else:
            this_nobs = dict_apply(nobs, lambda x: x.reshape(-1, *x.shape[2:]))
            nobs_features = self.obs_encoder(this_nobs)
            nobs_features = nobs_features.reshape(batch_size, horizon, -1)
            trajectory = torch.cat([nactions, nobs_features], dim=-1).detach()
        if self.pred_action_steps_only:
            condition_mask = torch.zeros_like(trajectory, dtype=torch.bool)
        else:
            condition_mask = self.mask_generator(trajectory.shape)
        loss_mask = torch.zeros_like(trajectory, dtype=torch.bool)
        loss_mask[..., : self.action_dim] = True
        loss_mask = loss_mask & ~condition_mask
        x = trajectory
        e = torch.randn_like(x)
        t = torch.rand(batch_size, device=x.device, dtype=x.dtype)
        r = torch.rand(batch_size, device=x.device, dtype=x.dtype)
        t, r = torch.maximum(t, r), torch.minimum(t, r)
        t_broadcast = self._broadcast_batch_time(t, x)
        z_t = (1 - t_broadcast) * x + t_broadcast * e
        z_t = self._apply_conditioning(z_t, x, condition_mask)
        v = self.fn(z_t, t, t, cond=cond)
        u, du_dt = self._compute_u_and_du_dt(
            z_t,
            r,
            t,
            cond=cond,
            v=v,
            condition_data=x,
            condition_mask=condition_mask,
        )
        V = self._compound_velocity(u, du_dt, r, t)
        target = e - x
        loss = F.mse_loss(V, target, reduction='none')
        loss = loss * loss_mask.type(loss.dtype)
        loss = reduce(loss, 'b ... -> b (...)', 'mean')
        loss = loss.mean()
        return loss
--- a/image_pusht_diffusion_policy_dit_imf.yaml
+++ b/image_pusht_diffusion_policy_dit_imf.yaml
@@ -0,0 +1,30 @@
 defaults:
  - diffusion_policy/config/train_diffusion_transformer_hybrid_workspace@_here_
  - override /diffusion_policy/config/task@task: pusht_image
  - _self_
 exp_name: pusht_image_dit_imf
 policy:
  _target_: diffusion_policy.policy.imf_transformer_hybrid_image_policy.IMFTransformerHybridImagePolicy
  num_inference_steps: 1
  n_head: 1
 logging:
  backend: swanlab
  mode: online
  tags: ["${name}", "${task_name}", "${exp_name}", "swanlab"]
  id: ${now:%Y%m%d%H%M%S}_${name}_${task_name}
  group: ${exp_name}
 dataloader:
  num_workers: 0
 val_dataloader:
  num_workers: 0
 task:
  env_runner:
    n_envs: 1
    n_test_vis: 0
    n_train_vis: 0
--- a/tests/test_imf_transformer_for_diffusion.py
+++ b/tests/test_imf_transformer_for_diffusion.py
@@ -0,0 +1,46 @@
 import inspect
 import pathlib
 import sys
 import torch
 ROOT_DIR = pathlib.Path(__file__).resolve().parents[1]
 if str(ROOT_DIR) not in sys.path:
    sys.path.append(str(ROOT_DIR))
 from diffusion_policy.model.diffusion.imf_transformer_for_diffusion import (  # noqa: E402
    IMFTransformerForDiffusion,
 )
 def test_imf_transformer_forward_signature_and_shape_single_head():
    signature = inspect.signature(IMFTransformerForDiffusion.forward)
    assert list(signature.parameters)[:5] == ['self', 'sample', 'r', 't', 'cond']
    assert signature.parameters['cond'].default is None
    model = IMFTransformerForDiffusion(
        input_dim=3,
        output_dim=3,
        horizon=5,
        n_obs_steps=2,
        cond_dim=4,
        n_layer=1,
        n_head=1,
        n_emb=16,
        p_drop_emb=0.0,
        p_drop_attn=0.0,
        causal_attn=True,
        time_as_cond=True,
        obs_as_cond=True,
        n_cond_layers=0,
    )
    model.configure_optimizers()
    sample = torch.randn(2, 5, 3)
    r = torch.rand(2)
    t = torch.rand(2)
    cond = torch.randn(2, 2, 4)
    pred_u = model(sample, r, t, cond=cond)
    assert pred_u.shape == sample.shape
--- a/tests/test_imf_transformer_hybrid_image_policy.py
+++ b/tests/test_imf_transformer_hybrid_image_policy.py
@@ -0,0 +1,313 @@
 import pathlib
 import sys
 import pytest
 import torch
 import torch.nn as nn
 ROOT_DIR = pathlib.Path(__file__).resolve().parents[1]
 if str(ROOT_DIR) not in sys.path:
    sys.path.append(str(ROOT_DIR))
 import diffusion_policy.policy.imf_transformer_hybrid_image_policy as policy_module  # noqa: E402
 from diffusion_policy.model.common.module_attr_mixin import ModuleAttrMixin  # noqa: E402
 from diffusion_policy.policy.imf_transformer_hybrid_image_policy import (  # noqa: E402
    IMFTransformerHybridImagePolicy,
 )
 class ConstantModel(nn.Module):
    def __init__(self, value):
        super().__init__()
        self.value = value
    def forward(self, sample, r, t, cond=None):
        return torch.full_like(sample, self.value)
 class AffineModel(nn.Module):
    def __init__(self):
        super().__init__()
        self.weight = nn.Parameter(torch.tensor(2.0))
    def forward(self, sample, r, t, cond=None):
        return sample * self.weight + (r + t).view(-1, 1, 1)
 class SumMixModel(nn.Module):
    def __init__(self):
        super().__init__()
        self.weight = nn.Parameter(torch.tensor(2.0))
    def forward(self, sample, r, t, cond=None):
        mixed = sample.sum(dim=-1, keepdim=True).expand_as(sample)
        return mixed * self.weight + t.view(-1, 1, 1)
 class TrackingContext:
    def __init__(self):
        self.active = False
        self.enter_count = 0
    def __enter__(self):
        self.active = True
        self.enter_count += 1
        return self
    def __exit__(self, exc_type, exc, tb):
        self.active = False
        return False
 def make_policy(model):
    policy = IMFTransformerHybridImagePolicy.__new__(IMFTransformerHybridImagePolicy)
    ModuleAttrMixin.__init__(policy)
    policy.model = model
    return policy
 def fake_parent_init(
    self,
    shape_meta,
    noise_scheduler,
    horizon,
    n_action_steps,
    n_obs_steps,
    num_inference_steps=None,
    crop_shape=(76, 76),
    obs_encoder_group_norm=False,
    eval_fixed_crop=False,
    n_layer=8,
    n_cond_layers=0,
    n_head=1,
    n_emb=256,
    p_drop_emb=0.0,
    p_drop_attn=0.3,
    causal_attn=True,
    time_as_cond=True,
    obs_as_cond=True,
    pred_action_steps_only=False,
    **kwargs,
 ):
    ModuleAttrMixin.__init__(self)
    self.action_dim = shape_meta['action']['shape'][0]
    self.obs_feature_dim = 4
    self.obs_as_cond = obs_as_cond
    self.pred_action_steps_only = pred_action_steps_only
    self.n_action_steps = n_action_steps
    self.n_obs_steps = n_obs_steps
    self.horizon = horizon
@pytest.fixture
 def shape_meta():
    return {
        'action': {'shape': [2]},
        'obs': {},
    }
 def test_sample_one_step_uses_imf_update_formula():
    policy = make_policy(ConstantModel(0.25))
    z_1 = torch.tensor([
        [[1.0, -1.0], [0.5, 0.0]],
        [[2.0, 3.0], [-2.0, 4.0]],
    ])
    r = torch.zeros(z_1.shape[0])
    t = torch.ones(z_1.shape[0])
    x_hat = policy._sample_one_step(z_1, r=r, t=t, cond=None)
    expected = z_1 - (t - r).view(-1, 1, 1) * 0.25
    assert torch.allclose(x_hat, expected)
 def test_compound_velocity_uses_detached_du_dt_term():
    policy = make_policy(ConstantModel(0.0))
    u = torch.tensor([[[1.0], [2.0]]], requires_grad=True)
    du_dt = torch.tensor([[[3.0], [4.0]]], requires_grad=True)
    r = torch.tensor([0.2])
    t = torch.tensor([0.8])
    compound = policy._compound_velocity(u, du_dt, r, t)
    expected = u + (t - r).view(-1, 1, 1) * du_dt.detach()
    assert torch.allclose(compound, expected)
    compound.sum().backward()
    assert u.grad is not None
    assert du_dt.grad is None
 def test_compute_u_and_du_dt_uses_math_sdpa_context_for_torch_func_jvp(monkeypatch):
    tracker = TrackingContext()
    def fake_jvp(fn, primals, tangents):
        assert tracker.active is True
        return fn(*primals), torch.zeros_like(primals[0])
    monkeypatch.setattr(policy_module, 'TORCH_FUNC_JVP', fake_jvp)
    policy = make_policy(ConstantModel(0.5))
    policy._jvp_math_sdp_context = lambda tensor: tracker
    z_t = torch.randn(2, 3, 4)
    r = torch.rand(2, requires_grad=True)
    t = torch.rand(2, requires_grad=True)
    v = torch.randn_like(z_t, requires_grad=True)
    policy._compute_u_and_du_dt(z_t, r, t, cond=None, v=v)
    assert tracker.enter_count == 1
 def test_compute_u_and_du_dt_uses_math_sdpa_context_for_autograd_fallback(monkeypatch):
    tracker = TrackingContext()
    def fake_autograd_jvp(fn, primals, tangents, create_graph=False, strict=False):
        assert tracker.active is True
        return fn(*primals), torch.zeros_like(primals[0])
    monkeypatch.setattr(policy_module, 'TORCH_FUNC_JVP', None)
    monkeypatch.setattr(policy_module.torch.autograd.functional, 'jvp', fake_autograd_jvp)
    policy = make_policy(ConstantModel(0.5))
    policy._jvp_math_sdp_context = lambda tensor: tracker
    z_t = torch.randn(2, 3, 4)
    r = torch.rand(2, requires_grad=True)
    t = torch.rand(2, requires_grad=True)
    v = torch.randn_like(z_t, requires_grad=True)
    policy._compute_u_and_du_dt(z_t, r, t, cond=None, v=v)
    assert tracker.enter_count == 1
 def test_compute_u_and_du_dt_uses_detached_v_zero_r_unit_t_and_reapplies_conditioning(monkeypatch):
    captured = {}
    def fake_jvp(fn, primals, tangents):
        captured['tangents'] = tangents
        captured['primal_output'] = fn(*primals)
        return captured['primal_output'], torch.zeros_like(primals[0])
    monkeypatch.setattr(policy_module, 'TORCH_FUNC_JVP', fake_jvp)
    policy = make_policy(SumMixModel())
    z_t = torch.tensor([[[1.0, 2.0, 3.0]]])
    r = torch.rand(1, requires_grad=True)
    t = torch.rand(1, requires_grad=True)
    v = torch.tensor([[[10.0, 20.0, 30.0]]], requires_grad=True)
    condition_mask = torch.tensor([[[False, True, False]]])
    condition_data = torch.tensor([[[0.0, 7.0, 0.0]]])
    policy._compute_u_and_du_dt(
        z_t,
        r,
        t,
        cond=None,
        v=v,
        condition_data=condition_data,
        condition_mask=condition_mask,
    )
    tangent_v, tangent_r, tangent_t = captured['tangents']
    assert torch.equal(tangent_v, v.detach())
    assert tangent_v.requires_grad is False
    assert torch.equal(tangent_r, torch.zeros_like(r))
    assert torch.equal(tangent_t, torch.ones_like(t))
    conditioned = z_t.clone()
    conditioned[condition_mask] = condition_data[condition_mask]
    expected_primal = policy.model(conditioned, r, t, cond=None)
    assert torch.allclose(captured['primal_output'], expected_primal)
 def test_compute_u_and_du_dt_fallback_blocks_conditioned_tangent_leakage_and_keeps_primal_gradients(monkeypatch):
    monkeypatch.setattr(policy_module, 'TORCH_FUNC_JVP', None)
    policy = make_policy(SumMixModel())
    z_t = torch.tensor([[[1.0, 2.0, 3.0]]], requires_grad=True)
    r = torch.rand(1, requires_grad=True)
    t = torch.rand(1, requires_grad=True)
    v = torch.tensor([[[1.0, 10.0, 100.0]]], requires_grad=True)
    condition_mask = torch.tensor([[[False, True, False]]])
    condition_data = torch.tensor([[[0.0, 7.0, 0.0]]])
    u, du_dt = policy._compute_u_and_du_dt(
        z_t,
        r,
        t,
        cond=None,
        v=v,
        condition_data=condition_data,
        condition_mask=condition_mask,
    )
    conditioned = z_t.detach().clone()
    conditioned[condition_mask] = condition_data[condition_mask]
    expected_u = policy.model(conditioned, r, t, cond=None)
    expected_du_dt_scalar = policy.model.weight.detach() * torch.tensor(101.0) + 1.0
    expected_du_dt = torch.full_like(z_t, expected_du_dt_scalar)
    assert u.shape == z_t.shape
    assert du_dt.shape == z_t.shape
    assert torch.allclose(u, expected_u)
    assert torch.allclose(du_dt, expected_du_dt)
    u.sum().backward()
    assert policy.model.weight.grad is not None
    assert torch.count_nonzero(policy.model.weight.grad) > 0
 def test_init_uses_action_step_horizon_when_pred_action_steps_only(monkeypatch, shape_meta):
    monkeypatch.setattr(
        policy_module.DiffusionTransformerHybridImagePolicy,
        '__init__',
        fake_parent_init,
    )
    policy = IMFTransformerHybridImagePolicy(
        shape_meta=shape_meta,
        noise_scheduler=None,
        horizon=10,
        n_action_steps=4,
        n_obs_steps=2,
        num_inference_steps=1,
        n_layer=1,
        n_head=1,
        n_emb=16,
        p_drop_emb=0.0,
        p_drop_attn=0.0,
        causal_attn=True,
        obs_as_cond=True,
        pred_action_steps_only=True,
    )
    assert policy.model.horizon == 4
    assert policy.num_inference_steps == 1
 def test_init_rejects_non_one_step_inference(monkeypatch, shape_meta):
    monkeypatch.setattr(
        policy_module.DiffusionTransformerHybridImagePolicy,
        '__init__',
        fake_parent_init,
    )
    with pytest.raises(ValueError, match='num_inference_steps'):
        IMFTransformerHybridImagePolicy(
            shape_meta=shape_meta,
            noise_scheduler=None,
            horizon=10,
            n_action_steps=4,
            n_obs_steps=2,
            num_inference_steps=2,
            n_layer=1,
            n_head=1,
            n_emb=16,
            p_drop_emb=0.0,
            p_drop_attn=0.0,
            causal_attn=True,
            obs_as_cond=True,
            pred_action_steps_only=False,
        )