ArticleChatbot / document_qa /document_qa_engine.py
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add query analyzer with min and avg similarity
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import copy
import os
from pathlib import Path
from typing import Union, Any, List
import tiktoken
from langchain.chains import create_extraction_chain
from langchain.chains.question_answering import load_qa_chain, stuff_prompt, refine_prompts, map_reduce_prompt, \
map_rerank_prompt
from langchain.evaluation import PairwiseEmbeddingDistanceEvalChain, load_evaluator, EmbeddingDistance
from langchain.prompts import SystemMessagePromptTemplate, HumanMessagePromptTemplate, ChatPromptTemplate
from langchain.retrievers import MultiQueryRetriever
from langchain.schema import Document
from langchain_community.vectorstores.chroma import Chroma
from langchain_core.vectorstores import VectorStore
from tqdm import tqdm
# from document_qa.embedding_visualiser import QueryVisualiser
from document_qa.grobid_processors import GrobidProcessor
from document_qa.langchain import ChromaAdvancedRetrieval
class TextMerger:
"""
This class tries to replicate the RecursiveTextSplitter from LangChain, to preserve and merge the
coordinate information from the PDF document.
"""
def __init__(self, model_name=None, encoding_name="gpt2"):
if model_name is not None:
self.enc = tiktoken.encoding_for_model(model_name)
else:
self.enc = tiktoken.get_encoding(encoding_name)
def encode(self, text, allowed_special=set(), disallowed_special="all"):
return self.enc.encode(
text,
allowed_special=allowed_special,
disallowed_special=disallowed_special,
)
def merge_passages(self, passages, chunk_size, tolerance=0.2):
new_passages = []
new_coordinates = []
current_texts = []
current_coordinates = []
for idx, passage in enumerate(passages):
text = passage['text']
coordinates = passage['coordinates']
current_texts.append(text)
current_coordinates.append(coordinates)
accumulated_text = " ".join(current_texts)
encoded_accumulated_text = self.encode(accumulated_text)
if len(encoded_accumulated_text) > chunk_size + chunk_size * tolerance:
if len(current_texts) > 1:
new_passages.append(current_texts[:-1])
new_coordinates.append(current_coordinates[:-1])
current_texts = [current_texts[-1]]
current_coordinates = [current_coordinates[-1]]
else:
new_passages.append(current_texts)
new_coordinates.append(current_coordinates)
current_texts = []
current_coordinates = []
elif chunk_size <= len(encoded_accumulated_text) < chunk_size + chunk_size * tolerance:
new_passages.append(current_texts)
new_coordinates.append(current_coordinates)
current_texts = []
current_coordinates = []
if len(current_texts) > 0:
new_passages.append(current_texts)
new_coordinates.append(current_coordinates)
new_passages_struct = []
for i, passages in enumerate(new_passages):
text = " ".join(passages)
coordinates = ";".join(new_coordinates[i])
new_passages_struct.append(
{
"text": text,
"coordinates": coordinates,
"type": "aggregated chunks",
"section": "mixed",
"subSection": "mixed"
}
)
return new_passages_struct
class BaseRetrieval:
def __init__(
self,
persist_directory: Path,
embedding_function
):
self.embedding_function = embedding_function
self.persist_directory = persist_directory
class NER_Retrival(VectorStore):
"""
This class implement a retrieval based on NER models.
This is an alternative retrieval to embeddings that relies on extracted entities.
"""
pass
engines = {
'chroma': ChromaAdvancedRetrieval,
'ner': NER_Retrival
}
class DataStorage:
embeddings_dict = {}
embeddings_map_from_md5 = {}
embeddings_map_to_md5 = {}
def __init__(
self,
embedding_function,
root_path: Path = None,
engine=ChromaAdvancedRetrieval,
) -> None:
self.root_path = root_path
self.engine = engine
self.embedding_function = embedding_function
if root_path is not None:
self.embeddings_root_path = root_path
if not os.path.exists(root_path):
os.makedirs(root_path)
else:
self.load_embeddings(self.embeddings_root_path)
def load_embeddings(self, embeddings_root_path: Union[str, Path]) -> None:
"""
Load the vector storage assuming they are all persisted and stored in a single directory.
The root path of the embeddings containing one data store for each document in each subdirectory
"""
embeddings_directories = [f for f in os.scandir(embeddings_root_path) if f.is_dir()]
if len(embeddings_directories) == 0:
print("No available embeddings")
return
for embedding_document_dir in embeddings_directories:
self.embeddings_dict[embedding_document_dir.name] = self.engine(
persist_directory=embedding_document_dir.path,
embedding_function=self.embedding_function
)
filename_list = list(Path(embedding_document_dir).glob('*.storage_filename'))
if filename_list:
filenam = filename_list[0].name.replace(".storage_filename", "")
self.embeddings_map_from_md5[embedding_document_dir.name] = filenam
self.embeddings_map_to_md5[filenam] = embedding_document_dir.name
print("Embedding loaded: ", len(self.embeddings_dict.keys()))
def get_loaded_embeddings_ids(self):
return list(self.embeddings_dict.keys())
def get_md5_from_filename(self, filename):
return self.embeddings_map_to_md5[filename]
def get_filename_from_md5(self, md5):
return self.embeddings_map_from_md5[md5]
def embed_document(self, doc_id, texts, metadatas):
if doc_id not in self.embeddings_dict.keys():
self.embeddings_dict[doc_id] = self.engine.from_texts(texts,
embedding=self.embedding_function,
metadatas=metadatas,
collection_name=doc_id)
else:
# Workaround Chroma (?) breaking change
self.embeddings_dict[doc_id].delete_collection()
self.embeddings_dict[doc_id] = self.engine.from_texts(texts,
embedding=self.embedding_function,
metadatas=metadatas,
collection_name=doc_id)
self.embeddings_root_path = None
class DocumentQAEngine:
llm = None
qa_chain_type = None
default_prompts = {
'stuff': stuff_prompt,
'refine': refine_prompts,
"map_reduce": map_reduce_prompt,
"map_rerank": map_rerank_prompt
}
def __init__(self,
llm,
data_storage: DataStorage,
qa_chain_type="stuff",
grobid_url=None,
memory=None
):
self.llm = llm
self.memory = memory
self.chain = load_qa_chain(llm, chain_type=qa_chain_type)
self.text_merger = TextMerger()
self.data_storage = data_storage
if grobid_url:
self.grobid_processor = GrobidProcessor(grobid_url)
def query_document(
self,
query: str,
doc_id,
output_parser=None,
context_size=4,
extraction_schema=None,
verbose=False
) -> (Any, str):
# self.load_embeddings(self.embeddings_root_path)
if verbose:
print(query)
response, coordinates = self._run_query(doc_id, query, context_size=context_size)
response = response['output_text'] if 'output_text' in response else response
if verbose:
print(doc_id, "->", response)
if output_parser:
try:
return self._parse_json(response, output_parser), response
except Exception as oe:
print("Failing to parse the response", oe)
return None, response, coordinates
elif extraction_schema:
try:
chain = create_extraction_chain(extraction_schema, self.llm)
parsed = chain.run(response)
return parsed, response, coordinates
except Exception as oe:
print("Failing to parse the response", oe)
return None, response, coordinates
else:
return None, response, coordinates
def query_storage(self, query: str, doc_id, context_size=4) -> (List[Document], list):
"""
Returns the context related to a given query
"""
documents, coordinates = self._get_context(doc_id, query, context_size)
context_as_text = [doc.page_content for doc in documents]
return context_as_text, coordinates
def query_storage_and_embeddings(self, query: str, doc_id, context_size=4) -> List[Document]:
"""
Returns both the context and the embedding information from a given query
"""
db = self.data_storage.embeddings_dict[doc_id]
retriever = db.as_retriever(search_kwargs={"k": context_size}, search_type="similarity_with_embeddings")
relevant_documents = retriever.get_relevant_documents(query)
return relevant_documents
def analyse_query(self, query, doc_id, context_size=4):
db = self.data_storage.embeddings_dict[doc_id]
# retriever = db.as_retriever(
# search_kwargs={"k": context_size, 'score_threshold': 0.0},
# search_type="similarity_score_threshold"
# )
retriever = db.as_retriever(search_kwargs={"k": context_size}, search_type="similarity_with_embeddings")
relevant_documents = retriever.get_relevant_documents(query)
relevant_document_coordinates = [doc.metadata['coordinates'].split(";") if 'coordinates' in doc.metadata else []
for doc in
relevant_documents]
all_documents = db.get(include=['documents', 'metadatas', 'embeddings'])
# all_documents_embeddings = all_documents["embeddings"]
# query_embedding = db._embedding_function.embed_query(query)
# distance_evaluator = load_evaluator("pairwise_embedding_distance",
# embeddings=db._embedding_function,
# distance_metric=EmbeddingDistance.EUCLIDEAN)
# distance_evaluator.evaluate_string_pairs(query=query_embedding, documents="")
similarities = [doc.metadata['__similarity'] for doc in relevant_documents]
min_similarity = min(similarities)
mean_similarity = sum(similarities) / len(similarities)
coefficient = min_similarity - mean_similarity
return f"Coefficient: {coefficient}, (Min similarity {min_similarity}, Mean similarity: {mean_similarity})", relevant_document_coordinates
def _parse_json(self, response, output_parser):
system_message = "You are an useful assistant expert in materials science, physics, and chemistry " \
"that can process text and transform it to JSON."
human_message = """Transform the text between three double quotes in JSON.\n\n\n\n
{format_instructions}\n\nText: \"\"\"{text}\"\"\""""
system_message_prompt = SystemMessagePromptTemplate.from_template(system_message)
human_message_prompt = HumanMessagePromptTemplate.from_template(human_message)
prompt_template = ChatPromptTemplate.from_messages([system_message_prompt, human_message_prompt])
results = self.llm(
prompt_template.format_prompt(
text=response,
format_instructions=output_parser.get_format_instructions()
).to_messages()
)
parsed_output = output_parser.parse(results.content)
return parsed_output
def _run_query(self, doc_id, query, context_size=4) -> (List[Document], list):
relevant_documents, relevant_document_coordinates = self._get_context(doc_id, query, context_size)
response = self.chain.run(input_documents=relevant_documents,
question=query)
if self.memory:
self.memory.save_context({"input": query}, {"output": response})
return response, relevant_document_coordinates
def _get_context(self, doc_id, query, context_size=4) -> (List[Document], list):
db = self.data_storage.embeddings_dict[doc_id]
retriever = db.as_retriever(search_kwargs={"k": context_size})
relevant_documents = retriever.get_relevant_documents(query)
relevant_document_coordinates = [doc.metadata['coordinates'].split(";") if 'coordinates' in doc.metadata else []
for doc in
relevant_documents]
if self.memory and len(self.memory.buffer_as_messages) > 0:
relevant_documents.append(
Document(
page_content="""Following, the previous question and answers. Use these information only when in the question there are unspecified references:\n{}\n\n""".format(
self.memory.buffer_as_str))
)
return relevant_documents, relevant_document_coordinates
def get_full_context_by_document(self, doc_id):
"""
Return the full context from the document
"""
db = self.data_storage.embeddings_dict[doc_id]
docs = db.get()
return docs['documents']
def _get_context_multiquery(self, doc_id, query, context_size=4):
db = self.data_storage.embeddings_dict[doc_id].as_retriever(search_kwargs={"k": context_size})
multi_query_retriever = MultiQueryRetriever.from_llm(retriever=db, llm=self.llm)
relevant_documents = multi_query_retriever.get_relevant_documents(query)
return relevant_documents
def get_text_from_document(self, pdf_file_path, chunk_size=-1, perc_overlap=0.1, verbose=False):
"""
Extract text from documents using Grobid.
- if chunk_size is < 0, keeps each paragraph separately
- if chunk_size > 0, aggregate all paragraphs and split them again using an approximate chunk size
"""
if verbose:
print("File", pdf_file_path)
filename = Path(pdf_file_path).stem
coordinates = True # if chunk_size == -1 else False
structure = self.grobid_processor.process_structure(pdf_file_path, coordinates=coordinates)
biblio = structure['biblio']
biblio['filename'] = filename.replace(" ", "_")
if verbose:
print("Generating embeddings for:", hash, ", filename: ", filename)
texts = []
metadatas = []
ids = []
if chunk_size > 0:
new_passages = self.text_merger.merge_passages(structure['passages'], chunk_size=chunk_size)
else:
new_passages = structure['passages']
for passage in new_passages:
biblio_copy = copy.copy(biblio)
if len(str.strip(passage['text'])) > 0:
texts.append(passage['text'])
biblio_copy['type'] = passage['type']
biblio_copy['section'] = passage['section']
biblio_copy['subSection'] = passage['subSection']
biblio_copy['coordinates'] = passage['coordinates']
metadatas.append(biblio_copy)
# ids.append(passage['passage_id'])
ids = [id for id, t in enumerate(new_passages)]
return texts, metadatas, ids
def create_memory_embeddings(
self,
pdf_path,
doc_id=None,
chunk_size=500,
perc_overlap=0.1
):
texts, metadata, ids = self.get_text_from_document(
pdf_path,
chunk_size=chunk_size,
perc_overlap=perc_overlap)
if doc_id:
hash = doc_id
else:
hash = metadata[0]['hash']
self.data_storage.embed_document(hash, texts, metadata)
return hash
def create_embeddings(
self,
pdfs_dir_path: Path,
chunk_size=500,
perc_overlap=0.1,
include_biblio=False
):
input_files = []
for root, dirs, files in os.walk(pdfs_dir_path, followlinks=False):
for file_ in files:
if not (file_.lower().endswith(".pdf")):
continue
input_files.append(os.path.join(root, file_))
for input_file in tqdm(input_files, total=len(input_files), unit='document',
desc="Grobid + embeddings processing"):
md5 = self.calculate_md5(input_file)
data_path = os.path.join(self.data_storage.embeddings_root_path, md5)
if os.path.exists(data_path):
print(data_path, "exists. Skipping it ")
continue
# include = ["biblio"] if include_biblio else []
texts, metadata, ids = self.get_text_from_document(
input_file,
chunk_size=chunk_size,
perc_overlap=perc_overlap)
filename = metadata[0]['filename']
vector_db_document = Chroma.from_texts(texts,
metadatas=metadata,
embedding=self.embedding_function,
persist_directory=data_path)
vector_db_document.persist()
with open(os.path.join(data_path, filename + ".storage_filename"), 'w') as fo:
fo.write("")
@staticmethod
def calculate_md5(input_file: Union[Path, str]):
import hashlib
md5_hash = hashlib.md5()
with open(input_file, 'rb') as fi:
md5_hash.update(fi.read())
return md5_hash.hexdigest().upper()