Agentic GraphRAG Implementation with LlamaIndex and Vertex AI¶
GraphRAG Aproach¶
The GraphRAG involves two steps:
- Graph Generation - Creates Graph, builds communities and its summaries over the given document.
- Answer to the Query - Use summaries of the communities created from step-1 to answer the query.
Graph Generation:
Source Documents to Text Chunks: Source documents are divided into smaller text chunks for easier processing.
Text Chunks to Element Instances: Each text chunk is analyzed to identify and extract entities and relationships, resulting in a list of tuples that represent these elements.
Element Instances to Element Summaries: The extracted entities and relationships are summarized into descriptive text blocks for each element using the LLM.
Element Summaries to Graph Communities: These entities, relationships and summaries form a graph, which is subsequently partitioned into communities using algorithms using Heirarchical Leiden to establish a hierarchical structure.
Graph Communities to Community Summaries: The LLM generates summaries for each community, providing insights into the dataset’s overall topical structure and semantics.
Answering the Query:
Community Summaries to Global Answers: The summaries of the communities are utilized to respond to user queries. This involves generating intermediate answers, which are then consolidated into a comprehensive global answer.
GraphRAG Pipeline Components¶
Here are the different components we implemented to build all of the processes mentioned above.
Source Documents to Text Chunks: Implemented using
SentenceSplitterwith a chunk size of 1024 and chunk overlap of 20 tokens.Text Chunks to Element Instances AND Element Instances to Element Summaries: Implemented using
GraphRAGExtractor.Element Summaries to Graph Communities AND Graph Communities to Community Summaries: Implemented using
GraphRAGStore.Community Summaries to Global Answers: Implemented using
GraphQueryEngine.
Let's check into each of these components and build GraphRAG pipeline.
Installation¶
graspologic is used to use hierarchical_leiden for building communities.
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!pip install llama-index graspologic numpy==1.24.4 scipy==1.12.0
!pip install llama-index graspologic numpy==1.24.4 scipy==1.12.0
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!pip install --upgrade google-cloud-aiplatform llama-index-vector-stores-vertexaivectorsearch llama-index llama_index-llms-vertex
!pip install --upgrade google-cloud-aiplatform llama-index-vector-stores-vertexaivectorsearch llama-index llama_index-llms-vertex
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import IPython
app = IPython.Application.instance()
app.kernel.do_shutdown(True)
import IPython
app = IPython.Application.instance()
app.kernel.do_shutdown(True)
Authentication¶
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import sys
if "google.colab" in sys.modules:
from google.colab import auth
auth.authenticate_user()
import sys
if "google.colab" in sys.modules:
from google.colab import auth
auth.authenticate_user()
Set Google Cloud project information and initialize Vertex AI SDK¶
To get started using Vertex AI, you must have an existing Google Cloud project and enable the Vertex AI API.
Learn more about setting up a project and a development environment.
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PROJECT_ID = "<your project>" # @param {type:"string"}
LOCATION = "us-central1" # @param {type:"string"}
import vertexai
vertexai.init(project=PROJECT_ID, location=LOCATION)
PROJECT_ID = "" # @param {type:"string"}
LOCATION = "us-central1" # @param {type:"string"}
import vertexai
vertexai.init(project=PROJECT_ID, location=LOCATION)
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# import modules needed
from llama_index.core import (
StorageContext,
Settings,
VectorStoreIndex,
SummaryIndex,
SimpleDirectoryReader,
)
from llama_index.core.schema import TextNode
from llama_index.core.vector_stores.types import (
MetadataFilters,
MetadataFilter,
FilterOperator,
)
from llama_index.llms.vertex import Vertex
from llama_index.embeddings.vertex import VertexTextEmbedding
from llama_index.vector_stores.vertexaivectorsearch import VertexAIVectorStore
from typing import List, Optional
from llama_index.core.vector_stores import FilterCondition
from llama_index.core.tools import FunctionTool
from llama_index.core import SimpleDirectoryReader
from llama_index.core.node_parser import SentenceSplitter
from llama_index.core.tools import QueryEngineTool
from llama_index.core.vector_stores import MetadataFilters
from pathlib import Path
from llama_index.core.agent import FunctionCallingAgent
# import modules needed
from llama_index.core import (
StorageContext,
Settings,
VectorStoreIndex,
SummaryIndex,
SimpleDirectoryReader,
)
from llama_index.core.schema import TextNode
from llama_index.core.vector_stores.types import (
MetadataFilters,
MetadataFilter,
FilterOperator,
)
from llama_index.llms.vertex import Vertex
from llama_index.embeddings.vertex import VertexTextEmbedding
from llama_index.vector_stores.vertexaivectorsearch import VertexAIVectorStore
from typing import List, Optional
from llama_index.core.vector_stores import FilterCondition
from llama_index.core.tools import FunctionTool
from llama_index.core import SimpleDirectoryReader
from llama_index.core.node_parser import SentenceSplitter
from llama_index.core.tools import QueryEngineTool
from llama_index.core.vector_stores import MetadataFilters
from pathlib import Path
from llama_index.core.agent import FunctionCallingAgent
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# configure embedding model
embed_model = VertexTextEmbedding(
model_name="text-embedding-004",
project=PROJECT_ID,
location=LOCATION,
)
vertex_gemini = Vertex(
model="gemini-1.5-pro",
temperature=0,
context_window=100000,
additional_kwargs={},
)
# setup the index/query process, ie the embedding model (and completion if used)
Settings.embed_model = embed_model
Settings.llm = vertex_gemini
# configure embedding model
embed_model = VertexTextEmbedding(
model_name="text-embedding-004",
project=PROJECT_ID,
location=LOCATION,
)
vertex_gemini = Vertex(
model="gemini-1.5-pro",
temperature=0,
context_window=100000,
additional_kwargs={},
)
# setup the index/query process, ie the embedding model (and completion if used)
Settings.embed_model = embed_model
Settings.llm = vertex_gemini
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llm = vertex_gemini
llm = vertex_gemini
Load Data¶
Prepare documents as required by LlamaIndex
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urls = [
"https://openreview.net/pdf?id=VtmBAGCN7o",
"https://openreview.net/pdf?id=6PmJoRfdaK",
"https://openreview.net/pdf?id=LzPWWPAdY4",
"https://openreview.net/pdf?id=VTF8yNQM66",
"https://openreview.net/pdf?id=hSyW5go0v8",
"https://openreview.net/pdf?id=9WD9KwssyT",
"https://openreview.net/pdf?id=yV6fD7LYkF",
"https://openreview.net/pdf?id=hnrB5YHoYu",
"https://openreview.net/pdf?id=WbWtOYIzIK",
"https://openreview.net/pdf?id=c5pwL0Soay",
"https://openreview.net/pdf?id=TpD2aG1h0D",
]
papers = [
"metagpt.pdf",
"longlora.pdf",
"loftq.pdf",
"swebench.pdf",
"selfrag.pdf",
"zipformer.pdf",
"values.pdf",
"finetune_fair_diffusion.pdf",
"knowledge_card.pdf",
"metra.pdf",
"vr_mcl.pdf",
]
import requests
def download_file(url, file_path):
"""Downloads a file from a given URL and saves it to the specified file path.
Args:
url: The URL of the file to download.
file_path: The path to save the downloaded file.
"""
response = requests.get(url, stream=True)
response.raise_for_status() # Raise an exception for non-200 status codes
with open(file_path, "wb") as f:
for chunk in response.iter_content(chunk_size=1024):
if chunk: # Filter out keep-alive new chunks
f.write(chunk)
print(f"Downloaded file from {url} to {file_path}")
for url, paper in zip(urls, papers):
download_file(url, paper)
urls = [
"https://openreview.net/pdf?id=VtmBAGCN7o",
"https://openreview.net/pdf?id=6PmJoRfdaK",
"https://openreview.net/pdf?id=LzPWWPAdY4",
"https://openreview.net/pdf?id=VTF8yNQM66",
"https://openreview.net/pdf?id=hSyW5go0v8",
"https://openreview.net/pdf?id=9WD9KwssyT",
"https://openreview.net/pdf?id=yV6fD7LYkF",
"https://openreview.net/pdf?id=hnrB5YHoYu",
"https://openreview.net/pdf?id=WbWtOYIzIK",
"https://openreview.net/pdf?id=c5pwL0Soay",
"https://openreview.net/pdf?id=TpD2aG1h0D",
]
papers = [
"metagpt.pdf",
"longlora.pdf",
"loftq.pdf",
"swebench.pdf",
"selfrag.pdf",
"zipformer.pdf",
"values.pdf",
"finetune_fair_diffusion.pdf",
"knowledge_card.pdf",
"metra.pdf",
"vr_mcl.pdf",
]
import requests
def download_file(url, file_path):
"""Downloads a file from a given URL and saves it to the specified file path.
Args:
url: The URL of the file to download.
file_path: The path to save the downloaded file.
"""
response = requests.get(url, stream=True)
response.raise_for_status() # Raise an exception for non-200 status codes
with open(file_path, "wb") as f:
for chunk in response.iter_content(chunk_size=1024):
if chunk: # Filter out keep-alive new chunks
f.write(chunk)
print(f"Downloaded file from {url} to {file_path}")
for url, paper in zip(urls, papers):
download_file(url, paper)
GraphRAGExtractor¶
The GraphRAGExtractor class is designed to extract triples (subject-relation-object) from text and enrich them by adding descriptions for entities and relationships to their properties using an LLM.
This functionality is similar to that of the SimpleLLMPathExtractor, but includes additional enhancements to handle entity, relationship descriptions. For guidance on implementation, you may look at similar existing extractors.
Here's a breakdown of its functionality:
Key Components:
llm:The language model used for extraction.extract_prompt:A prompt template used to guide the LLM in extracting information.parse_fn:A function to parse the LLM's output into structured data.max_paths_per_chunk:Limits the number of triples extracted per text chunk.num_workers:For parallel processing of multiple text nodes.
Main Methods:
__call__:The entry point for processing a list of text nodes.acall:An asynchronous version of call for improved performance._aextract:The core method that processes each individual node.
Extraction Process:
For each input node (chunk of text):
- It sends the text to the LLM along with the extraction prompt.
- The LLM's response is parsed to extract entities, relationships, descriptions for entities and relations.
- Entities are converted into EntityNode objects. Entity description is stored in metadata
- Relationships are converted into Relation objects. Relationship description is stored in metadata.
- These are added to the node's metadata under KG_NODES_KEY and KG_RELATIONS_KEY.
NOTE: In the current implementation, we are using only relationship descriptions. In the next implementation, we will utilize entity descriptions during the retrieval stage.
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import asyncio
import nest_asyncio
nest_asyncio.apply()
from typing import Any, List, Callable, Optional, Union, Dict
from IPython.display import Markdown, display
from llama_index.core.async_utils import run_jobs
from llama_index.core.indices.property_graph.utils import (
default_parse_triplets_fn,
)
from llama_index.core.graph_stores.types import (
EntityNode,
KG_NODES_KEY,
KG_RELATIONS_KEY,
Relation,
)
from llama_index.core.llms.llm import LLM
from llama_index.core.prompts import PromptTemplate
from llama_index.core.prompts.default_prompts import (
DEFAULT_KG_TRIPLET_EXTRACT_PROMPT,
)
from llama_index.core.schema import TransformComponent, BaseNode
from llama_index.core.bridge.pydantic import BaseModel, Field
class GraphRAGExtractor(TransformComponent):
"""Extract triples from a graph.
Uses an LLM and a simple prompt + output parsing to extract paths (i.e. triples) and entity, relation descriptions from text.
Args:
llm (LLM):
The language model to use.
extract_prompt (Union[str, PromptTemplate]):
The prompt to use for extracting triples.
parse_fn (callable):
A function to parse the output of the language model.
num_workers (int):
The number of workers to use for parallel processing.
max_paths_per_chunk (int):
The maximum number of paths to extract per chunk.
"""
llm: LLM
extract_prompt: PromptTemplate
parse_fn: Callable
num_workers: int
max_paths_per_chunk: int
def __init__(
self,
llm: Optional[LLM] = None,
extract_prompt: Optional[Union[str, PromptTemplate]] = None,
parse_fn: Callable = default_parse_triplets_fn,
max_paths_per_chunk: int = 10,
num_workers: int = 4,
) -> None:
"""Init params."""
from llama_index.core import Settings
if isinstance(extract_prompt, str):
extract_prompt = PromptTemplate(extract_prompt)
super().__init__(
llm=llm or Settings.llm,
extract_prompt=extract_prompt or DEFAULT_KG_TRIPLET_EXTRACT_PROMPT,
parse_fn=parse_fn,
num_workers=num_workers,
max_paths_per_chunk=max_paths_per_chunk,
)
@classmethod
def class_name(cls) -> str:
return "GraphExtractor"
def __call__(
self, nodes: List[BaseNode], show_progress: bool = False, **kwargs: Any
) -> List[BaseNode]:
"""Extract triples from nodes."""
return asyncio.run(
self.acall(nodes, show_progress=show_progress, **kwargs)
)
async def _aextract(self, node: BaseNode) -> BaseNode:
"""Extract triples from a node."""
assert hasattr(node, "text")
text = node.get_content(metadata_mode="llm")
try:
llm_response = await self.llm.apredict(
self.extract_prompt,
text=text,
max_knowledge_triplets=self.max_paths_per_chunk,
)
entities, entities_relationship = self.parse_fn(llm_response)
except ValueError:
entities = []
entities_relationship = []
existing_nodes = node.metadata.pop(KG_NODES_KEY, [])
existing_relations = node.metadata.pop(KG_RELATIONS_KEY, [])
metadata = node.metadata.copy()
for entity, entity_type, description in entities:
metadata[
"entity_description"
] = description # Not used in the current implementation. But will be useful in future work.
entity_node = EntityNode(
name=entity, label=entity_type, properties=metadata
)
existing_nodes.append(entity_node)
metadata = node.metadata.copy()
for triple in entities_relationship:
subj, rel, obj, description = triple
subj_node = EntityNode(name=subj, properties=metadata)
obj_node = EntityNode(name=obj, properties=metadata)
metadata["relationship_description"] = description
rel_node = Relation(
label=rel,
source_id=subj_node.id,
target_id=obj_node.id,
properties=metadata,
)
existing_nodes.extend([subj_node, obj_node])
existing_relations.append(rel_node)
node.metadata[KG_NODES_KEY] = existing_nodes
node.metadata[KG_RELATIONS_KEY] = existing_relations
return node
async def acall(
self, nodes: List[BaseNode], show_progress: bool = False, **kwargs: Any
) -> List[BaseNode]:
"""Extract triples from nodes async."""
jobs = []
for node in nodes:
jobs.append(self._aextract(node))
return await run_jobs(
jobs,
workers=self.num_workers,
show_progress=show_progress,
desc="Extracting paths from text",
)
import asyncio
import nest_asyncio
nest_asyncio.apply()
from typing import Any, List, Callable, Optional, Union, Dict
from IPython.display import Markdown, display
from llama_index.core.async_utils import run_jobs
from llama_index.core.indices.property_graph.utils import (
default_parse_triplets_fn,
)
from llama_index.core.graph_stores.types import (
EntityNode,
KG_NODES_KEY,
KG_RELATIONS_KEY,
Relation,
)
from llama_index.core.llms.llm import LLM
from llama_index.core.prompts import PromptTemplate
from llama_index.core.prompts.default_prompts import (
DEFAULT_KG_TRIPLET_EXTRACT_PROMPT,
)
from llama_index.core.schema import TransformComponent, BaseNode
from llama_index.core.bridge.pydantic import BaseModel, Field
class GraphRAGExtractor(TransformComponent):
"""Extract triples from a graph.
Uses an LLM and a simple prompt + output parsing to extract paths (i.e. triples) and entity, relation descriptions from text.
Args:
llm (LLM):
The language model to use.
extract_prompt (Union[str, PromptTemplate]):
The prompt to use for extracting triples.
parse_fn (callable):
A function to parse the output of the language model.
num_workers (int):
The number of workers to use for parallel processing.
max_paths_per_chunk (int):
The maximum number of paths to extract per chunk.
"""
llm: LLM
extract_prompt: PromptTemplate
parse_fn: Callable
num_workers: int
max_paths_per_chunk: int
def __init__(
self,
llm: Optional[LLM] = None,
extract_prompt: Optional[Union[str, PromptTemplate]] = None,
parse_fn: Callable = default_parse_triplets_fn,
max_paths_per_chunk: int = 10,
num_workers: int = 4,
) -> None:
"""Init params."""
from llama_index.core import Settings
if isinstance(extract_prompt, str):
extract_prompt = PromptTemplate(extract_prompt)
super().__init__(
llm=llm or Settings.llm,
extract_prompt=extract_prompt or DEFAULT_KG_TRIPLET_EXTRACT_PROMPT,
parse_fn=parse_fn,
num_workers=num_workers,
max_paths_per_chunk=max_paths_per_chunk,
)
@classmethod
def class_name(cls) -> str:
return "GraphExtractor"
def __call__(
self, nodes: List[BaseNode], show_progress: bool = False, **kwargs: Any
) -> List[BaseNode]:
"""Extract triples from nodes."""
return asyncio.run(
self.acall(nodes, show_progress=show_progress, **kwargs)
)
async def _aextract(self, node: BaseNode) -> BaseNode:
"""Extract triples from a node."""
assert hasattr(node, "text")
text = node.get_content(metadata_mode="llm")
try:
llm_response = await self.llm.apredict(
self.extract_prompt,
text=text,
max_knowledge_triplets=self.max_paths_per_chunk,
)
entities, entities_relationship = self.parse_fn(llm_response)
except ValueError:
entities = []
entities_relationship = []
existing_nodes = node.metadata.pop(KG_NODES_KEY, [])
existing_relations = node.metadata.pop(KG_RELATIONS_KEY, [])
metadata = node.metadata.copy()
for entity, entity_type, description in entities:
metadata[
"entity_description"
] = description # Not used in the current implementation. But will be useful in future work.
entity_node = EntityNode(
name=entity, label=entity_type, properties=metadata
)
existing_nodes.append(entity_node)
metadata = node.metadata.copy()
for triple in entities_relationship:
subj, rel, obj, description = triple
subj_node = EntityNode(name=subj, properties=metadata)
obj_node = EntityNode(name=obj, properties=metadata)
metadata["relationship_description"] = description
rel_node = Relation(
label=rel,
source_id=subj_node.id,
target_id=obj_node.id,
properties=metadata,
)
existing_nodes.extend([subj_node, obj_node])
existing_relations.append(rel_node)
node.metadata[KG_NODES_KEY] = existing_nodes
node.metadata[KG_RELATIONS_KEY] = existing_relations
return node
async def acall(
self, nodes: List[BaseNode], show_progress: bool = False, **kwargs: Any
) -> List[BaseNode]:
"""Extract triples from nodes async."""
jobs = []
for node in nodes:
jobs.append(self._aextract(node))
return await run_jobs(
jobs,
workers=self.num_workers,
show_progress=show_progress,
desc="Extracting paths from text",
)
GraphRAGStore¶
The GraphRAGStore class is an extension of the SimplePropertyGraphStore class, designed to implement GraphRAG pipeline. Here's a breakdown of its key components and functions:
The class uses community detection algorithms to group related nodes in the graph and then it generates summaries for each community using an LLM.
Key Methods:
build_communities():
Converts the internal graph representation to a NetworkX graph.
Applies the hierarchical Leiden algorithm for community detection.
Collects detailed information about each community.
Generates summaries for each community.
generate_community_summary(text):
- Uses LLM to generate a summary of the relationships in a community.
- The summary includes entity names and a synthesis of relationship descriptions.
_create_nx_graph():
- Converts the internal graph representation to a NetworkX graph for community detection.
_collect_community_info(nx_graph, clusters):
- Collects detailed information about each node based on its community.
- Creates a string representation of each relationship within a community.
_summarize_communities(community_info):
- Generates and stores summaries for each community using LLM.
get_community_summaries():
- Returns the community summaries by building them if not already done.
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import re
from llama_index.core.graph_stores import SimplePropertyGraphStore
import networkx as nx
from graspologic.partition import hierarchical_leiden
from llama_index.core.llms import ChatMessage
class GraphRAGStore(SimplePropertyGraphStore):
community_summary = {}
max_cluster_size = 5
def generate_community_summary(self, text):
"""Generate summary for a given text using an LLM."""
messages = [
ChatMessage(
role="system",
content=(
"You are provided with a set of relationships from a knowledge graph, each represented as "
"entity1->entity2->relation->relationship_description. Your task is to create a summary of these "
"relationships. The summary should include the names of the entities involved and a concise synthesis "
"of the relationship descriptions. The goal is to capture the most critical and relevant details that "
"highlight the nature and significance of each relationship. Ensure that the summary is coherent and "
"integrates the information in a way that emphasizes the key aspects of the relationships."
),
),
ChatMessage(role="user", content=text),
]
response = llm.chat(messages)
clean_response = re.sub(r"^assistant:\s*", "", str(response)).strip()
return clean_response
def build_communities(self):
"""Builds communities from the graph and summarizes them."""
nx_graph = self._create_nx_graph()
community_hierarchical_clusters = hierarchical_leiden(
nx_graph, max_cluster_size=self.max_cluster_size
)
community_info = self._collect_community_info(
nx_graph, community_hierarchical_clusters
)
self._summarize_communities(community_info)
def _create_nx_graph(self):
"""Converts internal graph representation to NetworkX graph."""
nx_graph = nx.Graph()
for node in self.graph.nodes.values():
nx_graph.add_node(str(node))
for relation in self.graph.relations.values():
nx_graph.add_edge(
relation.source_id,
relation.target_id,
relationship=relation.label,
description=relation.properties["relationship_description"],
)
return nx_graph
def _collect_community_info(self, nx_graph, clusters):
"""Collect detailed information for each node based on their community."""
community_mapping = {item.node: item.cluster for item in clusters}
community_info = {}
for item in clusters:
cluster_id = item.cluster
node = item.node
if cluster_id not in community_info:
community_info[cluster_id] = []
for neighbor in nx_graph.neighbors(node):
if community_mapping[neighbor] == cluster_id:
edge_data = nx_graph.get_edge_data(node, neighbor)
if edge_data:
detail = f"{node} -> {neighbor} -> {edge_data['relationship']} -> {edge_data['description']}"
community_info[cluster_id].append(detail)
return community_info
def _summarize_communities(self, community_info):
"""Generate and store summaries for each community."""
for community_id, details in community_info.items():
details_text = (
"\n".join(details) + "."
) # Ensure it ends with a period
self.community_summary[
community_id
] = self.generate_community_summary(details_text)
def get_community_summaries(self):
"""Returns the community summaries, building them if not already done."""
if not self.community_summary:
self.build_communities()
return self.community_summary
import re
from llama_index.core.graph_stores import SimplePropertyGraphStore
import networkx as nx
from graspologic.partition import hierarchical_leiden
from llama_index.core.llms import ChatMessage
class GraphRAGStore(SimplePropertyGraphStore):
community_summary = {}
max_cluster_size = 5
def generate_community_summary(self, text):
"""Generate summary for a given text using an LLM."""
messages = [
ChatMessage(
role="system",
content=(
"You are provided with a set of relationships from a knowledge graph, each represented as "
"entity1->entity2->relation->relationship_description. Your task is to create a summary of these "
"relationships. The summary should include the names of the entities involved and a concise synthesis "
"of the relationship descriptions. The goal is to capture the most critical and relevant details that "
"highlight the nature and significance of each relationship. Ensure that the summary is coherent and "
"integrates the information in a way that emphasizes the key aspects of the relationships."
),
),
ChatMessage(role="user", content=text),
]
response = llm.chat(messages)
clean_response = re.sub(r"^assistant:\s*", "", str(response)).strip()
return clean_response
def build_communities(self):
"""Builds communities from the graph and summarizes them."""
nx_graph = self._create_nx_graph()
community_hierarchical_clusters = hierarchical_leiden(
nx_graph, max_cluster_size=self.max_cluster_size
)
community_info = self._collect_community_info(
nx_graph, community_hierarchical_clusters
)
self._summarize_communities(community_info)
def _create_nx_graph(self):
"""Converts internal graph representation to NetworkX graph."""
nx_graph = nx.Graph()
for node in self.graph.nodes.values():
nx_graph.add_node(str(node))
for relation in self.graph.relations.values():
nx_graph.add_edge(
relation.source_id,
relation.target_id,
relationship=relation.label,
description=relation.properties["relationship_description"],
)
return nx_graph
def _collect_community_info(self, nx_graph, clusters):
"""Collect detailed information for each node based on their community."""
community_mapping = {item.node: item.cluster for item in clusters}
community_info = {}
for item in clusters:
cluster_id = item.cluster
node = item.node
if cluster_id not in community_info:
community_info[cluster_id] = []
for neighbor in nx_graph.neighbors(node):
if community_mapping[neighbor] == cluster_id:
edge_data = nx_graph.get_edge_data(node, neighbor)
if edge_data:
detail = f"{node} -> {neighbor} -> {edge_data['relationship']} -> {edge_data['description']}"
community_info[cluster_id].append(detail)
return community_info
def _summarize_communities(self, community_info):
"""Generate and store summaries for each community."""
for community_id, details in community_info.items():
details_text = (
"\n".join(details) + "."
) # Ensure it ends with a period
self.community_summary[
community_id
] = self.generate_community_summary(details_text)
def get_community_summaries(self):
"""Returns the community summaries, building them if not already done."""
if not self.community_summary:
self.build_communities()
return self.community_summary
GraphRAGQueryEngine¶
The GraphRAGQueryEngine class is a custom query engine designed to process queries using the GraphRAG approach. It leverages the community summaries generated by the GraphRAGStore to answer user queries. Here's a breakdown of its functionality:
Main Components:
graph_store: An instance of GraphRAGStore, which contains the community summaries.
llm: A Language Model (LLM) used for generating and aggregating answers.
Key Methods:
custom_query(query_str: str)
- This is the main entry point for processing a query. It retrieves community summaries, generates answers from each summary, and then aggregates these answers into a final response.
generate_answer_from_summary(community_summary, query):
- Generates an answer for the query based on a single community summary. Uses the LLM to interpret the community summary in the context of the query.
aggregate_answers(community_answers):
- Combines individual answers from different communities into a coherent final response.
- Uses the LLM to synthesize multiple perspectives into a single, concise answer.
Query Processing Flow:
- Retrieve community summaries from the graph store.
- For each community summary, generate a specific answer to the query.
- Aggregate all community-specific answers into a final, coherent response.
Example usage:
query_engine = GraphRAGQueryEngine(graph_store=graph_store, llm=llm)
response = query_engine.query("query")
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from llama_index.core.query_engine import CustomQueryEngine
from llama_index.core.llms import LLM
class GraphRAGQueryEngine(CustomQueryEngine):
graph_store: GraphRAGStore
llm: LLM
def custom_query(self, query_str: str) -> str:
"""Process all community summaries to generate answers to a specific query."""
community_summaries = self.graph_store.get_community_summaries()
community_answers = [
self.generate_answer_from_summary(community_summary, query_str)
for _, community_summary in community_summaries.items()
]
final_answer = self.aggregate_answers(community_answers)
return final_answer
def generate_answer_from_summary(self, community_summary, query):
"""Generate an answer from a community summary based on a given query using LLM."""
prompt = (
f"Given the community summary: {community_summary}, "
f"how would you answer the following query? Query: {query}"
)
messages = [
ChatMessage(role="system", content=prompt),
ChatMessage(
role="user",
content="I need an answer based on the above information.",
),
]
response = self.llm.chat(messages)
cleaned_response = re.sub(r"^assistant:\s*", "", str(response)).strip()
return cleaned_response
def aggregate_answers(self, community_answers):
"""Aggregate individual community answers into a final, coherent response."""
# intermediate_text = " ".join(community_answers)
prompt = "Combine the following intermediate answers into a final, concise response."
messages = [
ChatMessage(role="system", content=prompt),
ChatMessage(
role="user",
content=f"Intermediate answers: {community_answers}",
),
]
final_response = self.llm.chat(messages)
cleaned_final_response = re.sub(
r"^assistant:\s*", "", str(final_response)
).strip()
return cleaned_final_response
from llama_index.core.query_engine import CustomQueryEngine
from llama_index.core.llms import LLM
class GraphRAGQueryEngine(CustomQueryEngine):
graph_store: GraphRAGStore
llm: LLM
def custom_query(self, query_str: str) -> str:
"""Process all community summaries to generate answers to a specific query."""
community_summaries = self.graph_store.get_community_summaries()
community_answers = [
self.generate_answer_from_summary(community_summary, query_str)
for _, community_summary in community_summaries.items()
]
final_answer = self.aggregate_answers(community_answers)
return final_answer
def generate_answer_from_summary(self, community_summary, query):
"""Generate an answer from a community summary based on a given query using LLM."""
prompt = (
f"Given the community summary: {community_summary}, "
f"how would you answer the following query? Query: {query}"
)
messages = [
ChatMessage(role="system", content=prompt),
ChatMessage(
role="user",
content="I need an answer based on the above information.",
),
]
response = self.llm.chat(messages)
cleaned_response = re.sub(r"^assistant:\s*", "", str(response)).strip()
return cleaned_response
def aggregate_answers(self, community_answers):
"""Aggregate individual community answers into a final, coherent response."""
# intermediate_text = " ".join(community_answers)
prompt = "Combine the following intermediate answers into a final, concise response."
messages = [
ChatMessage(role="system", content=prompt),
ChatMessage(
role="user",
content=f"Intermediate answers: {community_answers}",
),
]
final_response = self.llm.chat(messages)
cleaned_final_response = re.sub(
r"^assistant:\s*", "", str(final_response)
).strip()
return cleaned_final_response
Build End to End GraphRAG Pipeline¶
Now that we have defined all the necessary components, let’s construct the GraphRAG pipeline:
- Create nodes/chunks from the text.
- Build a PropertyGraphIndex using
GraphRAGExtractorandGraphRAGStore. - Construct communities and generate a summary for each community using the graph built above.
- Create a
GraphRAGQueryEngineand begin querying.
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# load documents
documents = SimpleDirectoryReader(input_files=["metagpt.pdf"]).load_data()
# load documents
documents = SimpleDirectoryReader(input_files=["metagpt.pdf"]).load_data()
Create nodes/ chunks from the text.¶
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from llama_index.core.node_parser import SentenceSplitter
splitter = SentenceSplitter(
chunk_size=1024,
chunk_overlap=20,
)
nodes = splitter.get_nodes_from_documents(documents)
from llama_index.core.node_parser import SentenceSplitter
splitter = SentenceSplitter(
chunk_size=1024,
chunk_overlap=20,
)
nodes = splitter.get_nodes_from_documents(documents)
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len(nodes)
len(nodes)
Build PropertyGraphIndex using GraphRAGExtractor and GraphRAGStore¶
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KG_TRIPLET_EXTRACT_TMPL = """
-Goal-
Given a text document, identify all entities and their entity types from the text and all relationships among the identified entities.
Given the text, extract up to {max_knowledge_triplets} entity-relation triplets.
-Steps-
1. Identify all entities. For each identified entity, extract the following information:
- entity_name: Name of the entity, capitalized
- entity_type: Type of the entity
- entity_description: Comprehensive description of the entity's attributes and activities
Format each entity as ("entity"$$$$<entity_name>$$$$<entity_type>$$$$<entity_description>)
2. From the entities identified in step 1, identify all pairs of (source_entity, target_entity) that are *clearly related* to each other.
For each pair of related entities, extract the following information:
- source_entity: name of the source entity, as identified in step 1
- target_entity: name of the target entity, as identified in step 1
- relation: relationship between source_entity and target_entity
- relationship_description: explanation as to why you think the source entity and the target entity are related to each other
Format each relationship as ("relationship"$$$$<source_entity>$$$$<target_entity>$$$$<relation>$$$$<relationship_description>)
3. When finished, output.
-Real Data-
######################
text: {text}
######################
output:"""
KG_TRIPLET_EXTRACT_TMPL = """
-Goal-
Given a text document, identify all entities and their entity types from the text and all relationships among the identified entities.
Given the text, extract up to {max_knowledge_triplets} entity-relation triplets.
-Steps-
1. Identify all entities. For each identified entity, extract the following information:
- entity_name: Name of the entity, capitalized
- entity_type: Type of the entity
- entity_description: Comprehensive description of the entity's attributes and activities
Format each entity as ("entity"$$$$$$$$$$$$)
2. From the entities identified in step 1, identify all pairs of (source_entity, target_entity) that are *clearly related* to each other.
For each pair of related entities, extract the following information:
- source_entity: name of the source entity, as identified in step 1
- target_entity: name of the target entity, as identified in step 1
- relation: relationship between source_entity and target_entity
- relationship_description: explanation as to why you think the source entity and the target entity are related to each other
Format each relationship as ("relationship"$$$$$$$$$$$$$$$$)
3. When finished, output.
-Real Data-
######################
text: {text}
######################
output:"""
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entity_pattern = r'\("entity"\$\$\$\$"(.+?)"\$\$\$\$"(.+?)"\$\$\$\$"(.+?)"\)'
relationship_pattern = r'\("relationship"\$\$\$\$"(.+?)"\$\$\$\$"(.+?)"\$\$\$\$"(.+?)"\$\$\$\$"(.+?)"\)'
def parse_fn(response_str: str) -> Any:
entities = re.findall(entity_pattern, response_str)
relationships = re.findall(relationship_pattern, response_str)
return entities, relationships
kg_extractor = GraphRAGExtractor(
llm=llm,
extract_prompt=KG_TRIPLET_EXTRACT_TMPL,
max_paths_per_chunk=2,
parse_fn=parse_fn,
)
entity_pattern = r'\("entity"\$\$\$\$"(.+?)"\$\$\$\$"(.+?)"\$\$\$\$"(.+?)"\)'
relationship_pattern = r'\("relationship"\$\$\$\$"(.+?)"\$\$\$\$"(.+?)"\$\$\$\$"(.+?)"\$\$\$\$"(.+?)"\)'
def parse_fn(response_str: str) -> Any:
entities = re.findall(entity_pattern, response_str)
relationships = re.findall(relationship_pattern, response_str)
return entities, relationships
kg_extractor = GraphRAGExtractor(
llm=llm,
extract_prompt=KG_TRIPLET_EXTRACT_TMPL,
max_paths_per_chunk=2,
parse_fn=parse_fn,
)
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from llama_index.core import PropertyGraphIndex
index = PropertyGraphIndex(
nodes=nodes,
property_graph_store=GraphRAGStore(),
kg_extractors=[kg_extractor],
show_progress=True,
)
from llama_index.core import PropertyGraphIndex
index = PropertyGraphIndex(
nodes=nodes,
property_graph_store=GraphRAGStore(),
kg_extractors=[kg_extractor],
show_progress=True,
)
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list(index.property_graph_store.graph.nodes.values())[-1]
list(index.property_graph_store.graph.nodes.values())[-1]
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list(index.property_graph_store.graph.relations.values())[0]
list(index.property_graph_store.graph.relations.values())[0]
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list(index.property_graph_store.graph.relations.values())[0].properties[
"relationship_description"
]
list(index.property_graph_store.graph.relations.values())[0].properties[
"relationship_description"
]
Build communities¶
This will create communities and summary for each community.
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index.property_graph_store.build_communities()
index.property_graph_store.build_communities()
Create QueryEngine¶
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query_engine = GraphRAGQueryEngine(
graph_store=index.property_graph_store, llm=llm
)
query_engine = GraphRAGQueryEngine(
graph_store=index.property_graph_store, llm=llm
)
Querying¶
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response = query_engine.query("What are the main discussed in the document?")
display(Markdown(f"{response.response}"))
response = query_engine.query("What are the main discussed in the document?")
display(Markdown(f"{response.response}"))
Building an Agent Reasoning Loop¶
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def get_doc_tools(
file_path: str,
name: str,
) -> str:
"""Get vector query and summary query tools from a document."""
# load documents
documents = SimpleDirectoryReader(input_files=[file_path]).load_data()
splitter = SentenceSplitter(chunk_size=1024)
nodes = splitter.get_nodes_from_documents(documents)
index = PropertyGraphIndex(
nodes=nodes,
property_graph_store=GraphRAGStore(),
kg_extractors=[kg_extractor],
show_progress=True,
)
index.property_graph_store.build_communities()
query_engine = GraphRAGQueryEngine(
graph_store=index.property_graph_store, llm=llm
)
summary_index = SummaryIndex(nodes)
def vector_query(
query: str, page_numbers: Optional[List[str]] = None
) -> str:
"""Use to answer questions over the MetaGPT paper.
Useful if you have specific questions over the MetaGPT paper.
Always leave page_numbers as None UNLESS there is a specific page you want to search for.
Args:
query (str): the string query to be embedded.
page_numbers (Optional[List[str]]): Filter by set of pages. Leave as NONE
if we want to perform a vector search
over all pages. Otherwise, filter by the set of specified pages.
"""
vector_query_engine = query_engine
response = vector_query_engine.query(query)
return response
vector_query_tool = FunctionTool.from_defaults(
name=f"vector_tool_{name}", fn=vector_query
)
def summary_query(
query: str,
) -> str:
"""Perform a summary of document
query (str): the string query to be embedded.
"""
summary_engine = summary_index.as_query_engine(
response_mode="tree_summarize",
use_async=True,
)
response = summary_engine.query(query)
return response
summary_tool = FunctionTool.from_defaults(
fn=summary_query, name=f"summary_tool_{name}"
)
return vector_query_tool, summary_tool
def get_doc_tools(
file_path: str,
name: str,
) -> str:
"""Get vector query and summary query tools from a document."""
# load documents
documents = SimpleDirectoryReader(input_files=[file_path]).load_data()
splitter = SentenceSplitter(chunk_size=1024)
nodes = splitter.get_nodes_from_documents(documents)
index = PropertyGraphIndex(
nodes=nodes,
property_graph_store=GraphRAGStore(),
kg_extractors=[kg_extractor],
show_progress=True,
)
index.property_graph_store.build_communities()
query_engine = GraphRAGQueryEngine(
graph_store=index.property_graph_store, llm=llm
)
summary_index = SummaryIndex(nodes)
def vector_query(
query: str, page_numbers: Optional[List[str]] = None
) -> str:
"""Use to answer questions over the MetaGPT paper.
Useful if you have specific questions over the MetaGPT paper.
Always leave page_numbers as None UNLESS there is a specific page you want to search for.
Args:
query (str): the string query to be embedded.
page_numbers (Optional[List[str]]): Filter by set of pages. Leave as NONE
if we want to perform a vector search
over all pages. Otherwise, filter by the set of specified pages.
"""
vector_query_engine = query_engine
response = vector_query_engine.query(query)
return response
vector_query_tool = FunctionTool.from_defaults(
name=f"vector_tool_{name}", fn=vector_query
)
def summary_query(
query: str,
) -> str:
"""Perform a summary of document
query (str): the string query to be embedded.
"""
summary_engine = summary_index.as_query_engine(
response_mode="tree_summarize",
use_async=True,
)
response = summary_engine.query(query)
return response
summary_tool = FunctionTool.from_defaults(
fn=summary_query, name=f"summary_tool_{name}"
)
return vector_query_tool, summary_tool
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vector_query_tool, summary_tool = get_doc_tools("metagpt.pdf", "metagpt")
vector_query_tool, summary_tool = get_doc_tools("metagpt.pdf", "metagpt")
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# Create Agent Runner
agent = FunctionCallingAgent.from_tools(
[summary_tool, vector_query_tool], llm=vertex_gemini, verbose=True
)
# Create Agent Runner
agent = FunctionCallingAgent.from_tools(
[summary_tool, vector_query_tool], llm=vertex_gemini, verbose=True
)
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response = agent.query(
"what are agent roles in MetaGPT, "
"and then how they communicate with each other."
)
response = agent.query(
"what are agent roles in MetaGPT, "
"and then how they communicate with each other."
)
