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Conversational search
Conversational search is an experimental machine learning (ML) feature that enables a new search interface. Whereas traditional document search allows you to ask a question and receive a list of documents that might contain the answer to that question, conversational search uses large language models (LLMs) to read the top N documents and synthesizes those documents into a plaintext "answer" to your question.
Currently, conversational search uses two systems to synthesize documents:
Conversation memory
Conversation memory consists of a simple CRUD-life API comprising two resources: Conversations and Interactions. Conversations are made up of interactions. An interaction represents a pair of messages: a human input and an artificial intelligence (AI) response. You cannot create any interactions until you've created a conversation.
To make it easier to build and debug applications that use conversation memory, conversation-meta
and conversation-interactions
are stored in two system indexes.
conversation-meta
index
In the conversation-meta
index, you can customize the name
field to make it easier for end users to know how to continue a conversation with the AI, as shown in the following schema:
.plugins-ml-conversation-meta
{
"_meta": {
"schema_version": 1
},
"properties": {
"name": {"type": "keyword"},
"create_time": {"type": "date", "format": "strict_date_time||epoch_millis"},
"user": {"type": "keyword"}
}
}
conversation-interactions
index
In the conversation-interactions
index, all of the following fields are set by the user or AI application. Each field is entered as a string.
Field | Description |
---|---|
input |
The question that forms the basis for an interaction. |
prompt_template |
The prompt template that was used as the framework for this interaction. |
response |
The AI response to the prompt. |
origin |
The name of the AI or other system that generated the response. |
additional_info |
Any other information that was sent to the "origin" in the prompt. |
The conversation-interactions
index creates a clean interaction abstraction and make it easy for the index to reconstruct the exact prompts sent to the LLM, enabling robust debugging and explainability, as shown in the following schema:
.plugins-ml-conversation-interactions
{
"_meta": {
"schema_version": 1
},
"properties": {
"conversation_id": {"type": "keyword"},
"create_time": {"type": "date", "format": "strict_date_time||epoch_millis"},
"input": {"type": "text"},
"prompt_template": {"type": "text"},
"response": {"type": "text"},
"origin": {"type": "keyword"},
"additional_info": {"type": "text"}
}
}
Working with conversations and interactions
When the Security plugin is enabled, all conversations in ML Commons exist in a "private" security mode. Only the user who created a conversation can interact with that conversation. No users on the cluster can see another user's conversation. {: .note}
To begin using conversation memory, enable the following cluster setting:
PUT /_cluster/settings
{
"persistent": {
"plugins.ml_commons.memory_feature_enabled": true
}
}
After conversation memory is enabled, you can use the Memory API to create a conversation.
To make the conversation easily identifiable, use the optional name
field in the Memory API, as shown in the following example. This will be your only opportunity to name your conversation.
POST /_plugins/_ml/memory/conversation
{
"name": Example conversation
}
The Memory API responds with the conversation ID, as shown in the following example response:
{ "conversation_id": "4of2c9nhoIuhcr" }
You'll use the conversation_id
to create interactions inside the conversation. To create interactions, enter the conversation_id
into the Memory API path. Then customize the fields in the request body, as shown in the following example:
POST /_plugins/_ml/memory/conversation/4of2c9nhoIuhcr
{
"input": "How do I make an interaction?",
"prompt_template": "Hello OpenAI, can you answer this question? \
Here's some extra info that may help. \
[INFO] \n [QUESTION]",
"response": "Hello, this is OpenAI. Here is the answer to your question.",
"origin": "MyFirstOpenAIWrapper",
"additional_info": "Additional text related to the answer \
A JSON or other semi-structured response"
}
The Memory API then responds with an interaction ID, as shown in the following example response:
{ "interaction_id": "948vh_PoiY2hrnpo" }
Getting conversations
You can get a list of conversations using the following Memory API operation:
GET /_plugins/_ml/memory/conversation?max_results=3&next_token=0
Use the following path parameters to customize your results.
Parameter | Data type | Description |
---|---|---|
max_results |
Integer | The maximum number of results returned by the response. Default is 10 . |
next_token |
Integer | Represents the conversation order position that will be retrieved. For example, if conversations A, B, and C exist, next_token=1 would return conversations B and C. Default is 0 . |
The Memory API responds with the most recent conversation, as indicated in the create_time
field of the following example response:
{
"conversations": [
{
"conversation_id": "0y4hto_in1",
"name": "",
"create_time": "2023-4-23 10:25.324662"
}, ... (2 more since we specified max_results=3)
],
"next_token": 3
}
If there are fewer conversations than the number set in max_results
, the response only returns the number of conversations that exist. Lastly, next_token
provides an ordered position of the sorted list of conversations. When a conversation is added between subsequent GET conversation calls, one of the listed conversations will be duplicated in the results, for example:
GetConversations -> [BCD]EFGH
CreateConversation -> ABCDEFGH
GetConversations(next_token=3) -> ABC[DEF]GH
Getting interactions
To see a list of interactions in a conversation, enter the conversation_id
at the end of the API request, as shown in the following example. You can use max_results
and next_token
to sort the response:
GET /_plugins/_ml/memory/conversation/4of2c9nhoIuhcr
The Memory API returns the following interaction information:
{
"interactions": [
{
"interaction_id": "342968y2u4-0",
"conversation_id": "0y4hto_in1",
"create_time": "2023-4-23 10:25.324662",
"input": "How do I make an interaction?",
"prompt_template": "Hello OpenAI, can you answer this question? \
Here's some extra info that may help. \
[INFO] \n [QUESTION]",
"response": "Hello, this is OpenAI. Here is the answer to your question.",
"origin": "MyFirstOpenAIWrapper",
"additional_info": "Additional text related to the answer \
A JSON or other semi-structured response"
}, ... (9 more since max_results defaults to 10)
],
"next_token": 10
}
Deleting conversations
To delete a conversation, use the DELETE
operation, as showing in the following example:
DELETE /_plugins/_ml/memory/conversation/4of2c9nhoIuhcr
The Memory API responds with the following:
{ "success": true }
RAG pipeline
RAG is a technique that retrieves documents from an index, passes them through a seq2seq model, such as an LLM, and then generates more factual outputs.
Enabling RAG
Use the following cluster setting to enable the RAG pipeline feature:
PUT /_cluster/settings
{
"persistent": {"plugins.ml_commons.rag_pipline_feature_enabled": "true"}
}
Connecting the model
RAG requires an LLM in order to function. We recommend using a connector.
Use the following steps to set up an HTTP connector using the OpenAI GPT 3.5 model:
- Use the Connector API to create the HTTP connector:
POST /_plugins/_ml/connectors/_create
{
"name": "OpenAI Chat Connector",
"description": "The connector to public OpenAI model service for GPT 3.5",
"version": 2,
"protocol": "http",
"parameters": {
"endpoint": "[api.openai.com](http://api.openai.com/)",
"model": "gpt-3.5-turbo",
"temperature": 0
},
"credential": {
"openAI_key": "<your OpenAI key>"
},
"actions": [
{
"action_type": "predict",
"method": "POST",
"url": "[https://$](https://%24/){parameters.endpoint}/v1/chat/completions",
"headers": {
"Authorization": "Bearer ${credential.openAI_key}"
},
"request_body": "{ \"model\": \"${parameters.model}\", \"messages\": ${parameters.messages}, \"temperature\": $ {parameters.temperature} }"
}
]
}
-
Create a new model group for the connected model. You'll use the
model_group_id
returned by the Register API to register the model:
POST /_plugins/_ml/model_group/_register { "name": "public_model_group", "description": "This is a public model group" }
3. Register and deploy the model using the `connector_id` from the Connector API response in Step 1 and the `model_group_id` returned in Step 2:
```java
POST /_plugins/_ml/models/_register
{
"name": "openAI-gpt-3.5-turbo",
"function_name": "remote",
"model_group_id": "fp-hSYoBu0R6vVqGMnM1",
"description": "test model",
"connector_id": "f5-iSYoBu0R6vVqGI3PA"
}
- With the model registered, use the
task_id
returned in the registration response to get themodel_id
. You'll use themodel_id
to deploy the model to OpenSearch:
GET /_plugins/_ml/tasks/<task_id>
- Using the
model_id
from step 4, deploy the model:
POST /_plugins/_ml/models/<model_id>/_deploy
Setting up the pipeline
Next, you'll create a search pipeline for the connector model. Use the following Search API request to create a pipeline:
PUT /_search/pipeline/<pipeline_name>
{
"response_processors": [
{
"retrieval_augmented_generation": {
"tag": "openai_pipeline_demo",
"description": "Demo pipeline Using OpenAI Connector",
"model_id": "<model_id>",
"context_field_list": ["text"]
}
}
]
}
context_field_list
is the list of fields in document sources that the pipeline uses as context for the RAG. For example, when context_field_list
parses through the following document, the pipeline sends the text
field from the response to OpenAI model:
{
"_index": "qa_demo",
"_id": "SimKcIoBOVKVCYpk1IL-",
"_source": {
"title": "Abraham Lincoln 2",
"text": "Abraham Lincoln was born on February 12, 1809, the second child of Thomas Lincoln and Nancy Hanks Lincoln, in a log cabin on Sinking Spring Farm near Hodgenville, Kentucky.[2] He was a descendant of Samuel Lincoln, an Englishman who migrated from Hingham, Norfolk, to its namesake, Hingham, Massachusetts, in 1638. The family then migrated west, passing through New Jersey, Pennsylvania, and Virginia.[3] Lincoln was also a descendant of the Harrison family of Virginia; his paternal grandfather and namesake, Captain Abraham Lincoln and wife Bathsheba (née Herring) moved the family from Virginia to Jefferson County, Kentucky.[b] The captain was killed in an Indian raid in 1786.[5] His children, including eight-year-old Thomas, Abraham's father, witnessed the attack.[6][c] Thomas then worked at odd jobs in Kentucky and Tennessee before the family settled in Hardin County, Kentucky, in the early 1800s.[6]\n"
}
}
You can customize context_field_list
in your RAG pipeline to send any fields that exist in your documents to the LLM.
Using the pipeline
Using the pipeline is similar to submitting search queries to OpenSearch, as shown in the following example:
GET /<index_name>/_search?search_pipeline=<pipeline_name>
{
"query" : {...},
"ext": {
"generative_qa_parameters": {
"llm_model": "gpt-3.5-turbo",
"llm_question": "Was Abraham Lincoln a good politician",
"conversation_id": "_ikaSooBHvd8_FqDUOjZ"
}
}
}
The RAG search query uses the following request objects under the generative_qa_paramters
option.
Parameter | Required | Description |
---|---|---|
llm_question |
Yes | The question the LLM must answer. |
llm_model |
No | Overrides the original model set in the connection in cases where you want to use a different model (for example, GPT 4 instead of GPT 3.5). This option is required if a default model is not set during pipeline creation. |
coversation_id |
No | Integrates conversation memory into your RAG pipeline by adding the 10 most recent conversations into the context of the search query to the LLM. |
If your LLM includes a set token limit, set the size
field in your OpenSearch query to limit the number of documents used in the search response. Otherwise, the RAG pipeline will send every document in the search results to the LLM.
Next steps
- To learn more about ML connectors, see Creating connectors for third-party ML platforms.
- To learn more about the OpenSearch ML framework, see ML framework.