inputs.py

from abc import ABC, abstractmethod
from collections import UserDict, defaultdict
from collections.abc import Mapping, Sequence
from dataclasses import dataclass
from typing import (TYPE_CHECKING, Any, Literal, Optional, TypedDict, TypeVar,
                    Union, cast, final)

import numpy as np
import torch
import torch.types
from PIL.Image import Image
from transformers import BatchFeature
from typing_extensions import NotRequired, TypeAlias

from vllm.utils import JSONTree, full_groupby, is_list_of, json_map_leaves

if TYPE_CHECKING:
    from .hasher import MultiModalHashDict

_T = TypeVar("_T")

HfImageItem: TypeAlias = Union[Image, np.ndarray, torch.Tensor]
"""
A :class:`transformers.image_utils.ImageInput` representing a single image
item, which can be passed to a HuggingFace :code:`ImageProcessor`.
"""

HfVideoItem: TypeAlias = Union[list[Image], np.ndarray, torch.Tensor,
                               list[np.ndarray], list[torch.Tensor]]
"""
A :class:`transformers.image_utils.VideoInput` representing a single video
item, which can be passed to a HuggingFace :code:`VideoProcessor`.
"""

HfAudioItem: TypeAlias = Union[list[float], np.ndarray, torch.Tensor]
"""
Represents a single audio
item, which can be passed to a HuggingFace :code:`AudioProcessor`.
"""

ImageItem: TypeAlias = Union[HfImageItem, torch.Tensor]
"""
A :class:`transformers.image_utils.ImageInput` representing a single image
item, which can be passed to a HuggingFace :code:`ImageProcessor`.

Alternatively, a 3-D tensor or batch of 2-D tensors,
which are treated as image embeddings;
these are directly passed to the model without HF processing.
"""

VideoItem: TypeAlias = Union[HfVideoItem, torch.Tensor]
"""
A :class:`transformers.image_utils.VideoInput` representing a single video
item, which can be passed to a HuggingFace :code:`VideoProcessor`.

Alternatively, a 3-D tensor or batch of 2-D tensors,
which are treated as video embeddings;
these are directly passed to the model without HF processing.
"""

AudioItem: TypeAlias = Union[HfAudioItem, tuple[np.ndarray, float],
                             torch.Tensor]
"""
Represents a single audio
item, which can be passed to a HuggingFace :code:`AudioProcessor`.

Alternatively, a tuple `(audio, sampling_rate)`, where the sampling rate
is different from that expected by the model;
these are resampled to the model's sampling rate before being processed by HF.

Alternatively, a 3-D tensor or batch of 2-D tensors,
which are treated as audio embeddings;
these are directly passed to the model without HF processing.
"""

ModalityData: TypeAlias = Union[_T, list[_T]]
"""
Either a single data item, or a list of data items.

The number of data items allowed per modality is restricted by
:code:`--limit-mm-per-prompt`.
"""


@final
class MultiModalDataBuiltins(TypedDict, total=False):
    """Type annotations for modality types predefined by vLLM."""

    image: ModalityData[ImageItem]
    """The input image(s)."""

    video: ModalityData[VideoItem]
    """The input video(s)."""

    audio: ModalityData[AudioItem]
    """The input audio(s)."""


MultiModalDataDict: TypeAlias = Mapping[str, ModalityData[Any]]
"""
A dictionary containing an entry for each modality type to input.
"""


class PlaceholderRange(TypedDict):
    """
    Placeholder location information for multi-modal data.

    Example:

        Prompt: :code:`AAAA BBBB What is in these images?`

        Images A and B will have:

        .. code-block::

            A: { "offset": 0, "length": 4 }
            B: { "offset": 5, "length": 4 }
    """

    offset: int
    """The start index of the placeholder in the prompt."""

    length: int
    """The length of the placeholder."""


NestedTensors = Union[list["NestedTensors"], list[torch.Tensor], torch.Tensor,
                      tuple[torch.Tensor, ...]]
"""
Uses a list instead of a tensor if the dimensions of each element do not match.
"""


def nested_tensors_equal(a: NestedTensors, b: NestedTensors) -> bool:
    """Equality check between :data:`NestedTensors` objects."""
    if isinstance(a, torch.Tensor):
        return isinstance(b, torch.Tensor) and bool((a == b).all().item())
    elif isinstance(b, torch.Tensor):
        return isinstance(a, torch.Tensor) and bool((b == a).all().item())

    if isinstance(a, list):
        return (isinstance(b, list)
                and all(nested_tensors_equal(a_, b_) for a_, b_ in zip(a, b)))
    if isinstance(b, list):
        return (isinstance(a, list)
                and all(nested_tensors_equal(b_, a_) for b_, a_ in zip(b, a)))

    # Both a and b are scalars
    return a == b


BatchedTensorInputs: TypeAlias = Mapping[str, NestedTensors]
"""
A dictionary containing nested tensors which have been batched via
:meth:`MultiModalKwargs.batch`.
"""


@dataclass(frozen=True)
class MultiModalFieldElem:
    """Contains metadata and data of an item in :class:`MultiModalKwargs`."""
    field: "BaseMultiModalField"
    data: NestedTensors

    def __eq__(self, other: object) -> bool:
        if not isinstance(other, self.__class__):
            return False

        return (self.field == other.field
                and nested_tensors_equal(self.data, other.data))


@dataclass(frozen=True)
class BaseMultiModalField(ABC):
    """Abstract base class for a field in :class:`MultiModalKwargs`."""
    key: str
    modality: str

    @abstractmethod
    def _reduce_data(self, batch: list[NestedTensors]) -> NestedTensors:
        raise NotImplementedError

    def _build_elem(self, data: NestedTensors) -> MultiModalFieldElem:
        return MultiModalFieldElem(self, data)

    def reduce(self, batch: list[MultiModalFieldElem]) -> MultiModalFieldElem:
        """Merge multiple instances of :class:`MultiModalFieldElem` together."""
        fields = [item.field for item in batch]
        if len(set(fields)) > 1:
            raise ValueError(f"Cannot merge different {fields=}")

        data = self._reduce_data([item.data for item in batch])

        return self._build_elem(data)


@dataclass(frozen=True)
class MultiModalBatchedField(BaseMultiModalField):
    """
    A :class:`BaseMultiModalField` implementation where an element in the batch
    is obtained by indexing into the first dimension of the underlying data.
    """

    def build_elems(self, batch: NestedTensors) -> list[MultiModalFieldElem]:
        return [self._build_elem(item) for item in batch]

    def _reduce_data(self, batch: list[NestedTensors]) -> NestedTensors:
        if len(batch) > 0 and is_list_of(batch, torch.Tensor, check="all"):
            first_shape = batch[0].shape
            if all(elem.shape == first_shape for elem in batch):
                return torch.stack(batch)

        return batch


@dataclass(frozen=True)
class MultiModalFlatField(BaseMultiModalField):
    """
    A :class:`BaseMultiModalField` implementation where an element in the batch
    is obtained by slicing along the first dimension of the underlying data.
    """

    def build_elems(
        self,
        batch: NestedTensors,
        slices: Sequence[slice],
    ) -> list[MultiModalFieldElem]:
        return [self._build_elem(batch[slice_]) for slice_ in slices]

    def _reduce_data(self, batch: list[NestedTensors]) -> NestedTensors:
        if len(batch) > 0 and is_list_of(batch, torch.Tensor, check="all"):
            first_shape = batch[0].shape
            if all(elem.shape[1:] == first_shape[1:] for elem in batch):
                return torch.concat(batch)

        return [e for elem in batch for e in elem]


class MultiModalFieldConfig:

    @staticmethod
    def batched(modality: str):
        return MultiModalFieldConfig(
            field_cls=MultiModalBatchedField,
            modality=modality,
        )

    @staticmethod
    def flat(modality: str, slices: Sequence[slice]):
        return MultiModalFieldConfig(
            field_cls=MultiModalFlatField,
            modality=modality,
            slices=slices,
        )

    def __init__(
        self,
        field_cls: type[BaseMultiModalField],
        modality: str,
        **field_config: Any,
    ) -> None:
        super().__init__()

        self.field_cls = field_cls
        self.modality = modality
        self.field_config = field_config

    def build_elems(
        self,
        key: str,
        batch: NestedTensors,
    ) -> Sequence[MultiModalFieldElem]:
        field = self.field_cls(key=key, modality=self.modality)
        return field.build_elems(batch, **self.field_config)  # type: ignore


class MultiModalKwargsItem(UserDict[str, MultiModalFieldElem]):
    """
    A collection of :class:`MultiModalFieldElem`
    corresponding to a data item in :class:`MultiModalDataItems`.
    """

    @staticmethod
    def from_elems(elems: Sequence[MultiModalFieldElem]):
        return MultiModalKwargsItem({elem.field.key: elem for elem in elems})

    @property
    def modality(self) -> str:
        modalities = {elem.field.modality for elem in self.data.values()}
        assert len(modalities) == 1, f"Found different modalities={modalities}"
        return next(iter(modalities))


# NOTE: UserDict is for V0 compatibility.
# V1 should access individual items via `get_item`.
class MultiModalKwargs(UserDict[str, NestedTensors]):
    """
    A dictionary that represents the keyword arguments to
    :meth:`~torch.nn.Module.forward`.

    The metadata :code:`items` enables us to obtain the keyword arguments
    corresponding to each data item in :class:`MultiModalDataItems`, via
    :meth:`get_item` and :meth:`get_items`.
    """

    @staticmethod
    def from_hf_inputs(
        hf_inputs: BatchFeature,
        config_by_key: Mapping[str, MultiModalFieldConfig],
    ):
        # NOTE: This skips fields in `hf_inputs` that are not in `config_by_key`
        # We assume that those fields are not used in vLLM
        elems_by_key = dict[str, Sequence[MultiModalFieldElem]]()
        keys_by_modality = defaultdict[str, set[str]](set)
        for key, config in config_by_key.items():
            batch = hf_inputs.get(key)
            if batch is not None:
                elems = config.build_elems(key, batch)
                if len(elems) > 0:
                    elems_by_key[key] = elems
                    keys_by_modality[config.modality].add(key)

        items = list[MultiModalKwargsItem]()
        for modality, keys in keys_by_modality.items():
            elems_in_modality = {k: elems_by_key[k] for k in keys}
            batch_sizes = {k: len(v) for k, v in elems_in_modality.items()}

            if len(set(batch_sizes.values())) > 1:
                raise ValueError(
                    f"Cannot merge different batch sizes for {modality=}! "
                    f"Found: {batch_sizes=}")

            batch_size = next(iter(batch_sizes.values()))
            for item_idx in range(batch_size):
                elems = [v[item_idx] for v in elems_in_modality.values()]
                items.append(MultiModalKwargsItem.from_elems(elems))

        return MultiModalKwargs.from_items(items)

    @staticmethod
    def from_items(items: Sequence[MultiModalKwargsItem]):
        """Construct a new :class:`MultiModalKwargs` from multiple items."""
        elems_by_key = defaultdict[str, list[MultiModalFieldElem]](list)
        for item in items:
            for key, elem in item.items():
                elems_by_key[key].append(elem)

        data = {
            key: elems[0].field.reduce(elems).data
            for key, elems in elems_by_key.items() if len(elems) > 0
        }

        return MultiModalKwargs(data, items=items)

    def __init__(
        self,
        data: Mapping[str, NestedTensors],
        *,
        items: Optional[Sequence[MultiModalKwargsItem]] = None,
    ) -> None:
        super().__init__(data)

        items_by_modality = full_groupby(items or [], key=lambda x: x.modality)
        self._items_by_modality = dict(items_by_modality)

    @property
    def modalities(self):
        return self._items_by_modality.keys()

    @staticmethod
    def _try_stack(nested_tensors: NestedTensors) -> NestedTensors:
        """
        Stack the inner dimensions that have the same shape in
        a nested list of tensors.

        Thus, a dimension represented by a list means that the inner
        dimensions are different for each element along that dimension.
        """
        if isinstance(nested_tensors, torch.Tensor):
            return nested_tensors

        # TODO: Remove these once all models have been migrated
        if isinstance(nested_tensors, np.ndarray):
            return torch.from_numpy(nested_tensors)
        if isinstance(nested_tensors, (int, float)):
            return torch.tensor(nested_tensors)

        stacked = [MultiModalKwargs._try_stack(t) for t in nested_tensors]
        if not is_list_of(stacked, torch.Tensor, check="all"):
            # Only tensors (not lists) can be stacked.
            return stacked

        tensors_ = cast(list[torch.Tensor], stacked)
        if any(t.shape != tensors_[0].shape for t in tensors_):
            # The tensors have incompatible shapes and can't be stacked.
            return tensors_

        return torch.stack(tensors_)

    @staticmethod
    def batch(inputs_list: list["MultiModalKwargs"]) -> BatchedTensorInputs:
        """
        Batch multiple inputs together into a dictionary.

        The resulting dictionary has the same keys as the inputs.
        If the corresponding value from each input is a tensor and they all
        share the same shape, the output value is a single batched tensor;
        otherwise, the output value is a list containing the original value
        from each input.
        """
        if len(inputs_list) == 0:
            return {}

        # We need to consider the case where each item in the batch
        # contains different modalities (i.e. different keys).
        item_lists = defaultdict[str, list[NestedTensors]](list)

        for inputs in inputs_list:
            for k, v in inputs.items():
                item_lists[k].append(v)

        return {
            k: MultiModalKwargs._try_stack(item_list)
            for k, item_list in item_lists.items()
        }

    @staticmethod
    def as_kwargs(
        batched_inputs: BatchedTensorInputs,
        *,
        device: torch.types.Device,
    ) -> BatchedTensorInputs:
        json_inputs = cast(JSONTree[torch.Tensor], batched_inputs)

        json_mapped = json_map_leaves(
            lambda x: x.to(device, non_blocking=True),
            json_inputs,
        )

        return cast(BatchedTensorInputs, json_mapped)

    def __eq__(self, other: object) -> bool:
        if not isinstance(other, self.__class__):
            return False
        if self._items_by_modality != other._items_by_modality:
            return False

        ks = self.keys()
        return (ks == other.keys()
                and all(nested_tensors_equal(self[k], other[k]) for k in ks))

    def _validate_modality(self, method_name: str, modality: str) -> None:
        if not self._items_by_modality:
            raise RuntimeError(
                f"`{method_name}` is not supported when "
                "MultiModalKwargs is not initialized with `items`")

        if modality not in self._items_by_modality:
            available_modalities = set(self._items_by_modality.keys())
            raise KeyError(f"Modality {modality!r} not found. "
                           f"Available modalities: {available_modalities}")

    def get_item_count(self, modality: str) -> int:
        """Get the number of items belonging to a modality."""
        self._validate_modality("get_item_count", modality)
        return len(self._items_by_modality[modality])

    def get_item(self, modality: str, item_index: int) -> MultiModalKwargsItem:
        """
        Get the keyword arguments corresponding to an item identified by
        its modality and index.
        """
        self._validate_modality("get_item", modality)
        return self._items_by_modality[modality][item_index]

    def get_items(self, modality: str) -> Sequence[MultiModalKwargsItem]:
        """
        Get the keyword arguments corresponding to each item belonging to
        a modality.
        """
        self._validate_modality("get_items", modality)
        return self._items_by_modality[modality]


MultiModalPlaceholderDict = Mapping[str, Sequence[PlaceholderRange]]
"""
A dictionary containing placeholder ranges.
"""


class MultiModalInputsV2(TypedDict):
    """
    Represents the outputs of :class:`vllm.multimodal.MultiModalProcessor`,
    ready to be passed to vLLM internals.
    """

    type: Literal["multimodal"]
    """The type of inputs."""

    prompt: str
    """The processed prompt text."""

    prompt_token_ids: list[int]
    """The processed token IDs which includes placeholder tokens."""

    token_type_ids: NotRequired[list[int]]
    """The token type IDs of the prompt."""

    mm_kwargs: MultiModalKwargs
    """Keyword arguments to be directly passed to the model after batching."""

    mm_hashes: NotRequired[Optional["MultiModalHashDict"]]
    """The hashes of the multi-modal data."""

    mm_placeholders: MultiModalPlaceholderDict
    """
    For each modality, information about the placeholder tokens in
    :code:`prompt_token_ids`.
    """