Paper QA- Paper QA
- Paper QA- Paper QA
This is a minimal package for doing question and answering from PDFs or text files (which can be raw HTML). It strives to give very good answers, with no hallucinations, by grounding responses with in-text citations.
By default, it uses OpenAI Embeddings with a vector DB called FAISS to embed and search documents. However, via langchain you can use open-source models or embeddings (see details below).
PaperQA uses the process shown below:
- embed docs into vectors
- embed query into vector
- search for top k passages in docs
- create summary of each passage relevant to query
- put summaries into prompt
- generate answer with prompt
Question: How can carbon nanotubes be manufactured at a large scale?
Carbon nanotubes can be manufactured at a large scale using the electric-arc technique (Journet6644). This technique involves creating an arc between two electrodes in a reactor under a helium atmosphere and using a mixture of a metallic catalyst and graphite powder in the anode. Yields of 80% of entangled carbon filaments can be achieved, which consist of smaller aligned SWNTs self-organized into bundle-like crystallites (Journet6644). Additionally, carbon nanotubes can be synthesized and self-assembled using various methods such as DNA-mediated self-assembly, nanoparticle-assisted alignment, chemical self-assembly, and electro-addressed functionalization (Tulevski2007). These methods have been used to fabricate large-area nanostructured arrays, high-density integration, and freestanding networks (Tulevski2007). 98% semiconducting CNT network solution can also be used and is separated from metallic nanotubes using a density gradient ultracentrifugation approach (Chen2014). The substrate is incubated in the solution and then rinsed with deionized water and dried with N2 air gun, leaving a uniform carbon network (Chen2014).
Journet6644: Journet, Catherine, et al. "Large-scale production of single-walled carbon nanotubes by the electric-arc technique." nature 388.6644 (1997): 756-758.
Tulevski2007: Tulevski, George S., et al. "Chemically assisted directed assembly of carbon nanotubes for the fabrication of large-scale device arrays." Journal of the American Chemical Society 129.39 (2007): 11964-11968.
Chen2014: Chen, Haitian, et al. "Large-scale complementary macroelectronics using hybrid integration of carbon nanotubes and IGZO thin-film transistors." Nature communications 5.1 (2014): 4097.
Install with pip:
pip install paper-qa
Make sure you have set your OPENAI_API_KEY environment variable to your openai api key
To use paper-qa, you need to have a list of paths (valid extensions include: .pdf, .txt) and a list of citations (strings) that correspond to the paths. You can then use the Docs
class to add the documents and then query them. If you don't have citations, Docs
will try to guess them from the first page of your docs.
from paperqa import Docs
# get a list of paths
docs = Docs()
for d in my_docs:
docs.add(d)
answer = docs.query("What manufacturing challenges are unique to bispecific antibodies?")
print(answer.formatted_answer)
The answer object has the following attributes: formatted_answer
, answer
(answer alone), question
, context
(the summaries of passages found for answer), references
(the docs from which the passages came), and passages
which contain the raw text of the passages as a dictionary.
add
will add from paths. You can also use add_file
(expects a file object) or add_url
to work with other sources.
By default, it uses a hybrid of gpt-3.5-turbo
and gpt-4
. If you don't have gpt-4 access or would like to save money, you can adjust:
docs = Docs(llm='gpt-3.5-turbo')
or you can use any other model available in langchain:
from langchain.chat_models import ChatAnthropic, ChatOpenAI
model = ChatOpenAI(model='gpt-4')
summary_model = ChatAnthropic(model="claude-instant-v1-100k", anthropic_api_key="my-api-key")
docs = Docs(llm=model, summary_llm=summary_model)
You can also use any other models (or embeddings) available in langchain. Here's an example of using llama.cpp
to have locally hosted paper-qa:
import paperscraper
from paperqa import Docs
from langchain.llms import LlamaCpp
from langchain import PromptTemplate, LLMChain
from langchain.callbacks.manager import CallbackManager
from langchain.embeddings import LlamaCppEmbeddings
from langchain.callbacks.streaming_stdout import StreamingStdOutCallbackHandler
# Make sure the model path is correct for your system!
llm = LlamaCpp(
model_path="./ggml-model-q4_0.bin", callbacks=[StreamingStdOutCallbackHandler()]
)
embeddings = LlamaCppEmbeddings(model_path="./ggml-model-q4_0.bin")
docs = Docs(llm=llm, embeddings=embeddings)
keyword_search = 'bispecific antibody manufacture'
papers = paperscraper.search_papers(keyword_search, limit=2)
for path,data in papers.items():
try:
docs.add(path,chunk_chars=500)
except ValueError as e:
print('Could not read', path, e)
answer = docs.query("What manufacturing challenges are unique to bispecific antibodies?")
print(answer)
You can adjust the numbers of sources (passages of text) to reduce token usage or add more context. k
refers to the top k most relevant and diverse (may from different sources) passages. Each passage is sent to the LLM to summarize, or determine if it is irrelevant. After this step, a limit of max_sources
is applied so that the final answer can fit into the LLM context window. Thus, k
> max_sources
and max_sources
is the number of sources used in the final answer.
docs.query("What manufacturing challenges are unique to bispecific antibodies?", k = 5, max_sources = 2)
You do not need to use papers -- you can use code or raw HTML. Note that this tool is focused on answering questions, so it won't do well at writing code. One note is that the tool cannot infer citations from code, so you will need to provide them yourself.
import glob
source_files = glob.glob('**/*.js')
docs = Docs()
for f in source_files:
# this assumes the file names are unique in code
docs.add(f, citation='File ' + os.path.name(f), docname=os.path.name(f))
answer = docs.query("Where is the search bar in the header defined?")
print(answer)
Version 3 includes many changes to type the code, make it more focused/modular, and enable performance to very large numbers of documents. The major breaking changes are documented below:
The following new features are in v3:
- Memory is now possible in
query
by settingDocs(memory=True)
- this means follow-up questions will have a record of the previous question and answer. add_url
andadd_file
are now supported for adding from URLs and file objects- Prompts can be customized, and now can be executed pre and post query
- Consistent use of
dockey
anddocname
for unique and natural language names enable better tracking with external databases - Texts and embeddings are no longer required to be part of
Docs
object, so you can use external databases or other strategies to manage them - Various simplifications, bug fixes, and performance improvements
The following table shows the old names and the new names:
Old Name | New Name | Explanation |
---|---|---|
key |
name |
Name is a natural language name for text. |
dockey |
docname |
Docname is a natural language name for a document. |
hash |
dockey |
Dockey is a unique identifier for the document. |
The pickled objects are not compatible with the new version.
The agent functionality has been removed, as it's not a core focus of the library
Caching has been removed because it's not a core focus of the library. See FAQ below for how to use caching.
Answers will not include passages, but instead return dockeys that can be used to retrieve the passages. Tokens/cost will also not be counted since that is built into langchain by default (see below for an example).
The search query chain has been removed. You can use langchain directly to do this.
If you want to use this in an jupyter notebook or colab, you need to run the following command:
import nest_asyncio
nest_asyncio.apply()
Also - if you know how to make this automated, please let me know!
Well that's a really good question! It's probably best to just download PDFs of papers you think will help answer your question and start from there.
If you use Zotero to organize your personal bibliography,
you can use the paperqa.contrib.ZoteroDB
to query papers from your library,
which relies on pyzotero.
Install pyzotero
to use this feature:
pip install pyzotero
First, note that paperqa
parses the PDFs of papers to store in the database,
so all relevant papers should have PDFs stored inside your database.
You can get Zotero to automatically do this by highlighting the references
you wish to retrieve, right clicking, and selecting "Find Available PDFs".
You can also manually drag-and-drop PDFs onto each reference.
To download papers, you need to get an API key for your account.
- Get your library ID, and set it as the environment variable
ZOTERO_USER_ID
.- For personal libraries, this ID is given here at the part "Your userID for use in API calls is XXXXXX".
- For group libraries, go to your group page
https://www.zotero.org/groups/groupname
, and hover over the settings link. The ID is the integer after /groups/. (h/t pyzotero!)
- Create a new API key here and set it as the environment variable
ZOTERO_API_KEY
.- The key will need read access to the library.
With this, we can download papers from our library and add them to paperqa
:
from paperqa.contrib import ZoteroDB
docs = paperqa.Docs()
zotero = ZoteroDB(library_type="user") # "group" if group library
for item in zotero.iterate(limit=20):
if item.num_pages > 30:
continue # skip long papers
docs.add(item.pdf, docname=item.key)
which will download the first 20 papers in your Zotero database and add
them to the Docs
object.
We can also do specific queries of our Zotero library and iterate over the results:
for item in zotero.iterate(
q="large language models",
qmode="everything",
sort="date",
direction="desc",
limit=100,
):
print("Adding", item.title)
docs.add(item.pdf, docname=item.key)
You can read more about the search syntax by typing zotero.iterate?
in IPython.
If you want to search for papers outside of your own collection, I've found an unrelated project called paper-scraper that looks like it might help. But beware, this project looks like it uses some scraping tools that may violate publisher's rights or be in a gray area of legality.
keyword_search = 'bispecific antibody manufacture'
papers = paperscraper.search_papers(keyword_search)
docs = paperqa.Docs()
for path,data in papers.items():
try:
docs.add(path)
except ValueError as e:
# sometimes this happens if PDFs aren't downloaded or readable
print('Could not read', path, e)
answer = docs.query("What manufacturing challenges are unique to bispecific antibodies?")
print(answer)
By default PyPDF is used since it's pure python and easy to install. For faster PDF reading, paper-qa will detect and use PymuPDF (fitz):
pip install pymupdf
To stream the completions as they occur (giving that ChatGPT typewriter look), you can simply instantiate models with those properties:
from paperqa import Docs
from langchain.callbacks.manager import CallbackManager
from langchain.chat_models import ChatOpenAI
from langchain.callbacks.streaming_stdout import StreamingStdOutCallbackHandler
my_llm = ChatOpenAI(callbacks=[StreamingStdOutCallbackHandler()], streaming=True)
docs = Docs(llm=my_llm)
You can using the builtin langchain caching capabilities. Just run this code at the top of yours:
from langchain.cache import InMemoryCache
langchain.llm_cache = InMemoryCache()
In general, embeddings are cached when you pickle a Docs
regardless of what vector store you use. If you would like to manage caching embeddings via an external database or other strategy,
you can populate a Docs
object directly via
the add_texts
object. That can take chunked texts and documents, which are serializable objects, to populate Docs
.
You also can simply use a separate vector database by setting the doc_index
and texts_index
explicitly when building the Docs
object.
You can customize any of the prompts, using the PromptCollection
class. For example, if you want to change the prompt for the question, you can do:
from paperqa import Docs, Answer, PromptCollection
from langchain.prompts import PromptTemplate
my_qaprompt = PromptTemplate(
input_variables=["context", "question"],
template="Answer the question '{question}' "
"Use the context below if helpful. "
"You can cite the context using the key "
"like (Example2012). "
"If there is insufficient context, write a poem "
"about how you cannot answer.\n\n"
"Context: {context}\n\n")
prompts=PromptCollection(qa=my_qaprompt)
docs = Docs(prompts=prompts)
Following the syntax above, you can also include prompts that are executed after the query and before the query. For example, you can use this to critique the answer.
It's not that different! This is similar to the tree response method in LlamaIndex. I just have included some prompts I find useful, readers that give page numbers/line numbers, and am focused on one task - answering technical questions with cited sources.
It's not! We use langchain to abstract the LLMS, and the process is very similar to the map_reduce
chain in LangChain.
Yes, you can use any LLMs from langchain by passing the llm
argument to the Docs
class. You can use different LLMs for summarization and for question answering too.
You can provide your own. I use some of my own code to pull papers from Google Scholar. This code is not included because it may enable people to violate Google's terms of service and publisher's terms of service.
The Docs
class can be pickled and unpickled. This is useful if you want to save the embeddings of the documents and then load them later.
import pickle
# save
with open("my_docs.pkl", "wb") as f:
pickle.dump(docs, f)
# load
with open("my_docs.pkl", "rb") as f:
docs = pickle.load(f)