langchain/libs/community/langchain_community/vectorstores/cassandra.py

from __future__ import annotations

import typing
import uuid
from typing import (
    Any,
    Callable,
    Dict,
    Iterable,
    List,
    Optional,
    Tuple,
    Type,
    TypeVar,
    Union,
)

import numpy as np

if typing.TYPE_CHECKING:
    from cassandra.cluster import Session

from langchain_core.documents import Document
from langchain_core.embeddings import Embeddings
from langchain_core.vectorstores import VectorStore

from langchain_community.vectorstores.utils import maximal_marginal_relevance

CVST = TypeVar("CVST", bound="Cassandra")


class Cassandra(VectorStore):
    """Wrapper around Apache Cassandra(R) for vector-store workloads.

    To use it, you need a recent installation of the `cassio` library
    and a Cassandra cluster / Astra DB instance supporting vector capabilities.

    Visit the cassio.org website for extensive quickstarts and code examples.

    Example:
        .. code-block:: python

                from langchain_community.vectorstores import Cassandra
                from langchain_community.embeddings.openai import OpenAIEmbeddings

                embeddings = OpenAIEmbeddings()
                session = ...             # create your Cassandra session object
                keyspace = 'my_keyspace'  # the keyspace should exist already
                table_name = 'my_vector_store'
                vectorstore = Cassandra(embeddings, session, keyspace, table_name)
    """

    _embedding_dimension: Union[int, None]

    @staticmethod
    def _filter_to_metadata(filter_dict: Optional[Dict[str, str]]) -> Dict[str, Any]:
        if filter_dict is None:
            return {}
        else:
            return filter_dict

    def _get_embedding_dimension(self) -> int:
        if self._embedding_dimension is None:
            self._embedding_dimension = len(
                self.embedding.embed_query("This is a sample sentence.")
            )
        return self._embedding_dimension

    def __init__(
        self,
        embedding: Embeddings,
        session: Session,
        keyspace: str,
        table_name: str,
        ttl_seconds: Optional[int] = None,
    ) -> None:
        try:
            from cassio.table import MetadataVectorCassandraTable
        except (ImportError, ModuleNotFoundError):
            raise ImportError(
                "Could not import cassio python package. "
                "Please install it with `pip install cassio`."
            )
        """Create a vector table."""
        self.embedding = embedding
        self.session = session
        self.keyspace = keyspace
        self.table_name = table_name
        self.ttl_seconds = ttl_seconds
        #
        self._embedding_dimension = None
        #
        self.table = MetadataVectorCassandraTable(
            session=session,
            keyspace=keyspace,
            table=table_name,
            vector_dimension=self._get_embedding_dimension(),
            metadata_indexing="all",
            primary_key_type="TEXT",
        )

    @property
    def embeddings(self) -> Embeddings:
        return self.embedding

    @staticmethod
    def _dont_flip_the_cos_score(distance: float) -> float:
        # the identity
        return distance

    def _select_relevance_score_fn(self) -> Callable[[float], float]:
        """
        The underlying VectorTable already returns a "score proper",
        i.e. one in [0, 1] where higher means more *similar*,
        so here the final score transformation is not reversing the interval:
        """
        return self._dont_flip_the_cos_score

    def delete_collection(self) -> None:
        """
        Just an alias for `clear`
        (to better align with other VectorStore implementations).
        """
        self.clear()

    def clear(self) -> None:
        """Empty the collection."""
        self.table.clear()

    def delete_by_document_id(self, document_id: str) -> None:
        return self.table.delete(row_id=document_id)

    def delete(self, ids: Optional[List[str]] = None, **kwargs: Any) -> Optional[bool]:
        """Delete by vector IDs.


        Args:
            ids: List of ids to delete.

        Returns:
            Optional[bool]: True if deletion is successful,
            False otherwise, None if not implemented.
        """

        if ids is None:
            raise ValueError("No ids provided to delete.")

        for document_id in ids:
            self.delete_by_document_id(document_id)
        return True

    def add_texts(
        self,
        texts: Iterable[str],
        metadatas: Optional[List[dict]] = None,
        ids: Optional[List[str]] = None,
        batch_size: int = 16,
        ttl_seconds: Optional[int] = None,
        **kwargs: Any,
    ) -> List[str]:
        """Run more texts through the embeddings and add to the vectorstore.

        Args:
            texts (Iterable[str]): Texts to add to the vectorstore.
            metadatas (Optional[List[dict]], optional): Optional list of metadatas.
            ids (Optional[List[str]], optional): Optional list of IDs.
            batch_size (int): Number of concurrent requests to send to the server.
            ttl_seconds (Optional[int], optional): Optional time-to-live
                for the added texts.

        Returns:
            List[str]: List of IDs of the added texts.
        """
        _texts = list(texts)  # lest it be a generator or something
        if ids is None:
            ids = [uuid.uuid4().hex for _ in _texts]
        if metadatas is None:
            metadatas = [{} for _ in _texts]
        #
        ttl_seconds = ttl_seconds or self.ttl_seconds
        #
        embedding_vectors = self.embedding.embed_documents(_texts)
        #
        for i in range(0, len(_texts), batch_size):
            batch_texts = _texts[i : i + batch_size]
            batch_embedding_vectors = embedding_vectors[i : i + batch_size]
            batch_ids = ids[i : i + batch_size]
            batch_metadatas = metadatas[i : i + batch_size]

            futures = [
                self.table.put_async(
                    row_id=text_id,
                    body_blob=text,
                    vector=embedding_vector,
                    metadata=metadata or {},
                    ttl_seconds=ttl_seconds,
                )
                for text, embedding_vector, text_id, metadata in zip(
                    batch_texts, batch_embedding_vectors, batch_ids, batch_metadatas
                )
            ]
            for future in futures:
                future.result()
        return ids

    # id-returning search facilities
    def similarity_search_with_score_id_by_vector(
        self,
        embedding: List[float],
        k: int = 4,
        filter: Optional[Dict[str, str]] = None,
    ) -> List[Tuple[Document, float, str]]:
        """Return docs most similar to embedding vector.

        Args:
            embedding (str): Embedding to look up documents similar to.
            k (int): Number of Documents to return. Defaults to 4.
        Returns:
            List of (Document, score, id), the most similar to the query vector.
        """
        search_metadata = self._filter_to_metadata(filter)
        #
        hits = self.table.metric_ann_search(
            vector=embedding,
            n=k,
            metric="cos",
            metadata=search_metadata,
        )
        # We stick to 'cos' distance as it can be normalized on a 0-1 axis
        # (1=most relevant), as required by this class' contract.
        return [
            (
                Document(
                    page_content=hit["body_blob"],
                    metadata=hit["metadata"],
                ),
                0.5 + 0.5 * hit["distance"],
                hit["row_id"],
            )
            for hit in hits
        ]

    def similarity_search_with_score_id(
        self,
        query: str,
        k: int = 4,
        filter: Optional[Dict[str, str]] = None,
    ) -> List[Tuple[Document, float, str]]:
        embedding_vector = self.embedding.embed_query(query)
        return self.similarity_search_with_score_id_by_vector(
            embedding=embedding_vector,
            k=k,
            filter=filter,
        )

    # id-unaware search facilities
    def similarity_search_with_score_by_vector(
        self,
        embedding: List[float],
        k: int = 4,
        filter: Optional[Dict[str, str]] = None,
    ) -> List[Tuple[Document, float]]:
        """Return docs most similar to embedding vector.

        Args:
            embedding (str): Embedding to look up documents similar to.
            k (int): Number of Documents to return. Defaults to 4.
        Returns:
            List of (Document, score), the most similar to the query vector.
        """
        return [
            (doc, score)
            for (doc, score, docId) in self.similarity_search_with_score_id_by_vector(
                embedding=embedding,
                k=k,
                filter=filter,
            )
        ]

    def similarity_search(
        self,
        query: str,
        k: int = 4,
        filter: Optional[Dict[str, str]] = None,
        **kwargs: Any,
    ) -> List[Document]:
        embedding_vector = self.embedding.embed_query(query)
        return self.similarity_search_by_vector(
            embedding_vector,
            k,
            filter=filter,
        )

    def similarity_search_by_vector(
        self,
        embedding: List[float],
        k: int = 4,
        filter: Optional[Dict[str, str]] = None,
        **kwargs: Any,
    ) -> List[Document]:
        return [
            doc
            for doc, _ in self.similarity_search_with_score_by_vector(
                embedding,
                k,
                filter=filter,
            )
        ]

    def similarity_search_with_score(
        self,
        query: str,
        k: int = 4,
        filter: Optional[Dict[str, str]] = None,
    ) -> List[Tuple[Document, float]]:
        embedding_vector = self.embedding.embed_query(query)
        return self.similarity_search_with_score_by_vector(
            embedding_vector,
            k,
            filter=filter,
        )

    def max_marginal_relevance_search_by_vector(
        self,
        embedding: List[float],
        k: int = 4,
        fetch_k: int = 20,
        lambda_mult: float = 0.5,
        filter: Optional[Dict[str, str]] = None,
        **kwargs: Any,
    ) -> List[Document]:
        """Return docs selected using the maximal marginal relevance.
        Maximal marginal relevance optimizes for similarity to query AND diversity
        among selected documents.
        Args:
            embedding: Embedding to look up documents similar to.
            k: Number of Documents to return.
            fetch_k: Number of Documents to fetch to pass to MMR algorithm.
            lambda_mult: Number between 0 and 1 that determines the degree
                        of diversity among the results with 0 corresponding
                        to maximum diversity and 1 to minimum diversity.
        Returns:
            List of Documents selected by maximal marginal relevance.
        """
        search_metadata = self._filter_to_metadata(filter)

        prefetch_hits = list(
            self.table.metric_ann_search(
                vector=embedding,
                n=fetch_k,
                metric="cos",
                metadata=search_metadata,
            )
        )
        # let the mmr utility pick the *indices* in the above array
        mmr_chosen_indices = maximal_marginal_relevance(
            np.array(embedding, dtype=np.float32),
            [pf_hit["vector"] for pf_hit in prefetch_hits],
            k=k,
            lambda_mult=lambda_mult,
        )
        mmr_hits = [
            pf_hit
            for pf_index, pf_hit in enumerate(prefetch_hits)
            if pf_index in mmr_chosen_indices
        ]
        return [
            Document(
                page_content=hit["body_blob"],
                metadata=hit["metadata"],
            )
            for hit in mmr_hits
        ]

    def max_marginal_relevance_search(
        self,
        query: str,
        k: int = 4,
        fetch_k: int = 20,
        lambda_mult: float = 0.5,
        filter: Optional[Dict[str, str]] = None,
        **kwargs: Any,
    ) -> List[Document]:
        """Return docs selected using the maximal marginal relevance.
        Maximal marginal relevance optimizes for similarity to query AND diversity
        among selected documents.
        Args:
            query: Text to look up documents similar to.
            k: Number of Documents to return.
            fetch_k: Number of Documents to fetch to pass to MMR algorithm.
            lambda_mult: Number between 0 and 1 that determines the degree
                        of diversity among the results with 0 corresponding
                        to maximum diversity and 1 to minimum diversity.
                        Optional.
        Returns:
            List of Documents selected by maximal marginal relevance.
        """
        embedding_vector = self.embedding.embed_query(query)
        return self.max_marginal_relevance_search_by_vector(
            embedding_vector,
            k,
            fetch_k,
            lambda_mult=lambda_mult,
            filter=filter,
        )

    @classmethod
    def from_texts(
        cls: Type[CVST],
        texts: List[str],
        embedding: Embeddings,
        metadatas: Optional[List[dict]] = None,
        batch_size: int = 16,
        **kwargs: Any,
    ) -> CVST:
        """Create a Cassandra vectorstore from raw texts.

        No support for specifying text IDs

        Returns:
            a Cassandra vectorstore.
        """
        session: Session = kwargs["session"]
        keyspace: str = kwargs["keyspace"]
        table_name: str = kwargs["table_name"]
        cassandraStore = cls(
            embedding=embedding,
            session=session,
            keyspace=keyspace,
            table_name=table_name,
        )
        cassandraStore.add_texts(texts=texts, metadatas=metadatas)
        return cassandraStore

    @classmethod
    def from_documents(
        cls: Type[CVST],
        documents: List[Document],
        embedding: Embeddings,
        batch_size: int = 16,
        **kwargs: Any,
    ) -> CVST:
        """Create a Cassandra vectorstore from a document list.

        No support for specifying text IDs

        Returns:
            a Cassandra vectorstore.
        """
        texts = [doc.page_content for doc in documents]
        metadatas = [doc.metadata for doc in documents]
        session: Session = kwargs["session"]
        keyspace: str = kwargs["keyspace"]
        table_name: str = kwargs["table_name"]
        return cls.from_texts(
            texts=texts,
            metadatas=metadatas,
            embedding=embedding,
            session=session,
            keyspace=keyspace,
            table_name=table_name,
        )