You're viewing version 2.14 of the OpenSearch documentation. This version is no longer maintained. For the latest version, see the current documentation. For information about OpenSearch version maintenance, see Release Schedule and Maintenance Policy.
Semantic search using byte-quantized vectors
This tutorial illustrates how to build a semantic search using the Cohere Embed model and byte-quantized vectors. For more information about using byte-quantized vectors, see Lucene byte vector.
The Cohere Embed v3 model supports several embedding_types
. For this tutorial, you’ll use the INT8
type to encode byte-quantized vectors.
The Cohere Embed v3 model supports several input types. This tutorial uses the following input types:
search_document
: Use this input type when you have text (in the form of documents) that you want to store in a vector database.search_query
: Use this input type when structuring search queries to find the most relevant documents in your vector database.
For more information about input types, see the Cohere documentation.
In this tutorial, you will create two models:
- A model used for ingestion, whose
input_type
issearch_document
- A model used for search, whose
input_type
issearch_query
Replace the placeholders beginning with the prefix your_
with your own values.
Step 1: Create an embedding model for ingestion
Create a connector for the Cohere model, specifying the search_document
input type:
POST /_plugins/_ml/connectors/_create
{
"name": "Cohere embedding connector with int8 embedding type for ingestion",
"description": "Test connector for Cohere embedding model",
"version": 1,
"protocol": "http",
"credential": {
"cohere_key": "your_cohere_api_key"
},
"parameters": {
"model": "embed-english-v3.0",
"embedding_types": ["int8"],
"input_type": "search_document"
},
"actions": [
{
"action_type": "predict",
"method": "POST",
"headers": {
"Authorization": "Bearer ${credential.cohere_key}",
"Request-Source": "unspecified:opensearch"
},
"url": "https://api.cohere.ai/v1/embed",
"request_body": "{ \"model\": \"${parameters.model}\", \"texts\": ${parameters.texts}, \"input_type\":\"${parameters.input_type}\", \"embedding_types\": ${parameters.embedding_types} }",
"pre_process_function": "connector.pre_process.cohere.embedding",
"post_process_function": "\n def name = \"sentence_embedding\";\n def data_type = \"FLOAT32\";\n def result;\n if (params.embeddings.int8 != null) {\n data_type = \"INT8\";\n result = params.embeddings.int8;\n } else if (params.embeddings.uint8 != null) {\n data_type = \"UINT8\";\n result = params.embeddings.uint8;\n } else if (params.embeddings.float != null) {\n data_type = \"FLOAT32\";\n result = params.embeddings.float;\n }\n \n if (result == null) {\n return \"Invalid embedding result\";\n }\n \n def embedding_list = new StringBuilder(\"[\");\n \n for (int m=0; m<result.length; m++) {\n def embedding_size = result[m].length;\n def embedding = new StringBuilder(\"[\");\n def shape = [embedding_size];\n for (int i=0; i<embedding_size; i++) {\n def val;\n if (\"FLOAT32\".equals(data_type)) {\n val = result[m][i].floatValue();\n } else if (\"INT8\".equals(data_type) || \"UINT8\".equals(data_type)) {\n val = result[m][i].intValue();\n }\n embedding.append(val);\n if (i < embedding_size - 1) {\n embedding.append(\",\"); \n }\n }\n embedding.append(\"]\"); \n \n // workaround for compatible with neural-search\n def dummy_data_type = 'FLOAT32';\n \n def json = '{' +\n '\"name\":\"' + name + '\",' +\n '\"data_type\":\"' + dummy_data_type + '\",' +\n '\"shape\":' + shape + ',' +\n '\"data\":' + embedding +\n '}';\n embedding_list.append(json);\n if (m < result.length - 1) {\n embedding_list.append(\",\"); \n }\n }\n embedding_list.append(\"]\"); \n return embedding_list.toString();\n "
}
]
}
To ensure compatibility with the Neural Search plugin, the data_type
(output in the inference_results.output.data_type
field of the response) must be set to FLOAT32
in the post-processing function, even though the actual embedding type will be INT8
.
Note the connector ID in the response; you’ll use it to register the model.
Register the model, providing its connector ID:
POST /_plugins/_ml/models/_register?deploy=true
{
"name": "Cohere embedding model for INT8 with search_document input type",
"function_name": "remote",
"description": "test model",
"connector_id": "your_connector_id"
}
Note the model ID in the response; you’ll use it in the following steps.
Test the model, providing the model ID:
POST /_plugins/_ml/models/your_embedding_model_id/_predict
{
"parameters": {
"texts": ["hello", "goodbye"]
}
}
The response contains inference results:
{
"inference_results": [
{
"output": [
{
"name": "sentence_embedding",
"data_type": "FLOAT32",
"shape": [
1024
],
"data": [
20,
-11,
-60,
-91,
...
]
},
{
"name": "sentence_embedding",
"data_type": "FLOAT32",
"shape": [
1024
],
"data": [
58,
-30,
9,
-51,
...
]
}
],
"status_code": 200
}
]
}
Step 2: Ingest data
First, create an ingest pipeline:
PUT /_ingest/pipeline/pipeline-cohere
{
"description": "Cohere embedding ingest pipeline",
"processors": [
{
"text_embedding": {
"model_id": "your_embedding_model_id_created_in_step1",
"field_map": {
"passage_text": "passage_embedding"
}
}
}
]
}
Next, create a k-NN index and set the data_type
for the passage_embedding
field to byte
so that it can hold byte-quantized vectors:
PUT my_test_data
{
"settings": {
"index": {
"knn": true,
"knn.algo_param.ef_search": 100,
"default_pipeline": "pipeline-cohere"
}
},
"mappings": {
"properties": {
"passage_text": {
"type": "text"
},
"passage_embedding": {
"type": "knn_vector",
"dimension": 1024,
"data_type": "byte",
"method": {
"name": "hnsw",
"space_type": "l2",
"engine": "lucene",
"parameters": {
"ef_construction": 128,
"m": 24
}
}
}
}
}
}
Last, ingest test data:
POST _bulk
{ "index" : { "_index" : "my_test_data" } }
{ "passage_text" : "OpenSearch is the flexible, scalable, open-source way to build solutions for data-intensive applications. Explore, enrich, and visualize your data with built-in performance, developer-friendly tools, and powerful integrations for machine learning, data processing, and more." }
{ "index" : { "_index" : "my_test_data"} }
{ "passage_text" : "BM25 is a keyword-based algorithm that performs well on queries containing keywords but fails to capture the semantic meaning of the query terms. Semantic search, unlike keyword-based search, takes into account the meaning of the query in the search context. Thus, semantic search performs well when a query requires natural language understanding." }
Step 3: Configure semantic search
Create a connector to an embedding model with the search_query
input type:
POST /_plugins/_ml/connectors/_create
{
"name": "Cohere embedding connector with int8 embedding type for search",
"description": "Test connector for Cohere embedding model. Use this connector for search.",
"version": 1,
"protocol": "http",
"credential": {
"cohere_key": "your_cohere_api_key"
},
"parameters": {
"model": "embed-english-v3.0",
"embedding_types": ["int8"],
"input_type": "search_query"
},
"actions": [
{
"action_type": "predict",
"method": "POST",
"headers": {
"Authorization": "Bearer ${credential.cohere_key}",
"Request-Source": "unspecified:opensearch"
},
"url": "https://api.cohere.ai/v1/embed",
"request_body": "{ \"model\": \"${parameters.model}\", \"texts\": ${parameters.texts}, \"input_type\":\"${parameters.input_type}\", \"embedding_types\": ${parameters.embedding_types} }",
"pre_process_function": "connector.pre_process.cohere.embedding",
"post_process_function": "\n def name = \"sentence_embedding\";\n def data_type = \"FLOAT32\";\n def result;\n if (params.embeddings.int8 != null) {\n data_type = \"INT8\";\n result = params.embeddings.int8;\n } else if (params.embeddings.uint8 != null) {\n data_type = \"UINT8\";\n result = params.embeddings.uint8;\n } else if (params.embeddings.float != null) {\n data_type = \"FLOAT32\";\n result = params.embeddings.float;\n }\n \n if (result == null) {\n return \"Invalid embedding result\";\n }\n \n def embedding_list = new StringBuilder(\"[\");\n \n for (int m=0; m<result.length; m++) {\n def embedding_size = result[m].length;\n def embedding = new StringBuilder(\"[\");\n def shape = [embedding_size];\n for (int i=0; i<embedding_size; i++) {\n def val;\n if (\"FLOAT32\".equals(data_type)) {\n val = result[m][i].floatValue();\n } else if (\"INT8\".equals(data_type) || \"UINT8\".equals(data_type)) {\n val = result[m][i].intValue();\n }\n embedding.append(val);\n if (i < embedding_size - 1) {\n embedding.append(\",\"); \n }\n }\n embedding.append(\"]\"); \n \n // workaround for compatible with neural-search\n def dummy_data_type = 'FLOAT32';\n \n def json = '{' +\n '\"name\":\"' + name + '\",' +\n '\"data_type\":\"' + dummy_data_type + '\",' +\n '\"shape\":' + shape + ',' +\n '\"data\":' + embedding +\n '}';\n embedding_list.append(json);\n if (m < result.length - 1) {\n embedding_list.append(\",\"); \n }\n }\n embedding_list.append(\"]\"); \n return embedding_list.toString();\n "
}
]
}
Note the connector ID in the response; you’ll use it to register the model.
Register the model, providing its connector ID:
POST /_plugins/_ml/models/_register?deploy=true
{
"name": "Cohere embedding model for INT8 with search_document input type",
"function_name": "remote",
"description": "test model",
"connector_id": "your_connector_id"
}
Note the model ID in the response; you’ll use it to run queries.
Run a neural search query, providing the model ID:
POST /my_test_data/_search
{
"query": {
"neural": {
"passage_embedding": {
"query_text": "semantic search",
"model_id": "your_embedding_model_id",
"k": 100
}
}
},
"size": "1",
"_source": ["passage_text"]
}
The response contains the query results:
{
"took": 143,
"timed_out": false,
"_shards": {
"total": 1,
"successful": 1,
"skipped": 0,
"failed": 0
},
"hits": {
"total": {
"value": 2,
"relation": "eq"
},
"max_score": 9.345969e-7,
"hits": [
{
"_index": "my_test_data",
"_id": "_IXCuY0BJr_OiKWden7i",
"_score": 9.345969e-7,
"_source": {
"passage_text": "BM25 is a keyword-based algorithm that performs well on queries containing keywords but fails to capture the semantic meaning of the query terms. Semantic search, unlike keyword-based search, takes into account the meaning of the query in the search context. Thus, semantic search performs well when a query requires natural language understanding."
}
}
]
}
}