opensearch-docs-cn/_search-plugins/neural-text-search.md

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Add multimodal search/sparse search/pre- and post-processing function documentation (#5168) * Add multimodal search documentation Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Text image embedding processor Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Add prerequisite Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Change query text Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Added bedrock connector tutorial and renamed ML TOC Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Name changes and rewording Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Change connector link Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Change link Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Implemented tech review comments Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Link fix and field name fix Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Add default text embedding preprocessing and post-processing functions Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Add sparse search documentation Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Fix links Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Pre/post processing function tech review comments Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Fix link Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Sparse search tech review comments Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Apply suggestions from code review Co-authored-by: Melissa Vagi <vagimeli@amazon.com> Signed-off-by: kolchfa-aws <105444904+kolchfa-aws@users.noreply.github.com> * Implemented doc review comments Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Add actual test sparse pipeline response Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Added tested examples Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Added model choice for sparse search Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Remove Bedrock connector Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Implemented tech review feedback Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Add that the model must be deployed to neural search Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Apply suggestions from code review Co-authored-by: Nathan Bower <nbower@amazon.com> Signed-off-by: kolchfa-aws <105444904+kolchfa-aws@users.noreply.github.com> * Link fix Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Add session token to sagemaker blueprint Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Formatted bullet points the same way Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Specified both model types in neural sparse query Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Added more explanation for default pre/post-processing functions Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Remove framework and extensibility references Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> * Minor rewording Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> --------- Signed-off-by: Fanit Kolchina <kolchfa@amazon.com> Signed-off-by: kolchfa-aws <105444904+kolchfa-aws@users.noreply.github.com> Co-authored-by: Melissa Vagi <vagimeli@amazon.com> Co-authored-by: Nathan Bower <nbower@amazon.com>
2023-10-16 10:45:35 -04:00
---
layout: default
title: Text search
nav_order: 10
has_children: false
parent: Neural search
---
# Text search
Use text search for text data. In neural search, text search is facilitated by text embedding models. Text search creates a dense vector (a list of floats) and ingests data into a k-NN index.
**PREREQUISITE**<br>
Before using text search, you must set up a text embedding model. For more information, see [Using custom models within OpenSearch]({{site.url}}{{site.baseurl}}/ml-commons-plugin/ml-framework/).
{: .note}
## Using text search
To use text search, follow these steps:
1. [Create an ingest pipeline](#step-1-create-an-ingest-pipeline).
1. [Create an index for ingestion](#step-2-create-an-index-for-ingestion).
1. [Ingest documents into the index](#step-3-ingest-documents-into-the-index).
1. [Search the index using neural search](#step-4-search-the-index-using-neural-search).
## Step 1: Create an ingest pipeline
To generate vector embeddings, you need to create an [ingest pipeline]({{site.url}}{{site.baseurl}}/api-reference/ingest-apis/index/) that contains a [`text_embedding` processor]({{site.url}}{{site.baseurl}}/api-reference/ingest-apis/processors/text-embedding/), which will convert the text in a document field to vector embeddings. The processor's `field_map` determines the input fields from which to generate vector embeddings and the output fields in which to store the embeddings.
The following example request creates an ingest pipeline where the text from `passage_text` will be converted into text embeddings and the embeddings will be stored in `passage_embedding`:
```json
PUT /_ingest/pipeline/nlp-ingest-pipeline
{
"description": "A text embedding pipeline",
"processors": [
{
"text_embedding": {
"model_id": "bQ1J8ooBpBj3wT4HVUsb",
"field_map": {
"passage_text": "passage_embedding"
}
}
}
]
}
```
{% include copy-curl.html %}
## Step 2: Create an index for ingestion
In order to use the text embedding processor defined in your pipeline, create a k-NN index, adding the pipeline created in the previous step as the default pipeline. Ensure that the fields defined in the `field_map` are mapped as correct types. Continuing with the example, the `passage_embedding` field must be mapped as a k-NN vector with a dimension that matches the model dimension. Similarly, the `passage_text` field should be mapped as `text`.
The following example request creates a k-NN index that is set up with a default ingest pipeline:
```json
PUT /my-nlp-index
{
"settings": {
"index.knn": true,
"default_pipeline": "nlp-ingest-pipeline"
},
"mappings": {
"properties": {
"id": {
"type": "text"
},
"passage_embedding": {
"type": "knn_vector",
"dimension": 768,
"method": {
"engine": "lucene",
"space_type": "l2",
"name": "hnsw",
"parameters": {}
}
},
"passage_text": {
"type": "text"
}
}
}
}
```
{% include copy-curl.html %}
For more information about creating a k-NN index and its supported methods, see [k-NN index]({{site.url}}{{site.baseurl}}/search-plugins/knn/knn-index/).
## Step 3: Ingest documents into the index
To ingest documents into the index created in the previous step, send the following requests:
```json
PUT /my-nlp-index/_doc/1
{
"passage_text": "Hello world",
"id": "s1"
}
```
{% include copy-curl.html %}
```json
PUT /my-nlp-index/_doc/2
{
"passage_text": "Hi planet",
"id": "s2"
}
```
{% include copy-curl.html %}
Before the document is ingested into the index, the ingest pipeline runs the `text_embedding` processor on the document, generating text embeddings for the `passage_text` field. The indexed document includes the `passage_text` field, which contains the original text, and the `passage_embedding` field, which contains the vector embeddings.
## Step 4: Search the index using neural search
To perform vector search on your index, use the `neural` query clause either in the [k-NN plugin API]({{site.url}}{{site.baseurl}}/search-plugins/knn/api/#search-model) or [Query DSL]({{site.url}}{{site.baseurl}}/opensearch/query-dsl/index/) queries. You can refine the results by using a [k-NN search filter]({{site.url}}{{site.baseurl}}/search-plugins/knn/filter-search-knn/).
The following example request uses a Boolean query to combine a filter clause and two query clauses---a neural query and a `match` query. The `script_score` query assigns custom weights to the query clauses:
```json
GET /my-nlp-index/_search
{
"_source": {
"excludes": [
"passage_embedding"
]
},
"query": {
"bool": {
"filter": {
"wildcard": { "id": "*1" }
},
"should": [
{
"script_score": {
"query": {
"neural": {
"passage_embedding": {
"query_text": "Hi world",
"model_id": "bQ1J8ooBpBj3wT4HVUsb",
"k": 100
}
}
},
"script": {
"source": "_score * 1.5"
}
}
},
{
"script_score": {
"query": {
"match": {
"passage_text": "Hi world"
}
},
"script": {
"source": "_score * 1.7"
}
}
}
]
}
}
}
```
{% include copy-curl.html %}
The response contains the matching document:
```json
{
"took" : 36,
"timed_out" : false,
"_shards" : {
"total" : 1,
"successful" : 1,
"skipped" : 0,
"failed" : 0
},
"hits" : {
"total" : {
"value" : 1,
"relation" : "eq"
},
"max_score" : 1.2251667,
"hits" : [
{
"_index" : "my-nlp-index",
"_id" : "1",
"_score" : 1.2251667,
"_source" : {
"passage_text" : "Hello world",
"id" : "s1"
}
}
]
}
}
```
## Setting a default model on an index or field
A [`neural`]({{site.url}}{{site.baseurl}}/query-dsl/specialized/neural/) query requires a model ID for generating vector embeddings. To eliminate passing the model ID with each neural query request, you can set a default model on a k-NN index or a field.
First, create a [search pipeline]({{site.url}}{{site.baseurl}}/search-plugins/search-pipelines/index/) with a [`neural_query_enricher`]({{site.url}}{{site.baseurl}}/search-plugins/search-pipelines/neural-query-enricher/) request processor. To set a default model for an index, provide the model ID in the `default_model_id` parameter. To set a default model for a specific field, provide the field name and the corresponding model ID in the `neural_field_default_id` map. If you provide both `default_model_id` and `neural_field_default_id`, `neural_field_default_id` takes precedence:
```json
PUT /_search/pipeline/default_model_pipeline
{
"request_processors": [
{
"neural_query_enricher" : {
"default_model_id": "bQ1J8ooBpBj3wT4HVUsb",
"neural_field_default_id": {
"my_field_1": "uZj0qYoBMtvQlfhaYeud",
"my_field_2": "upj0qYoBMtvQlfhaZOuM"
}
}
}
]
}
```
{% include copy-curl.html %}
Then set the default model for your index:
```json
PUT /my-nlp-index/_settings
{
"index.search.default_pipeline" : "default_model_pipeline"
}
```
{% include copy-curl.html %}
You can now omit the model ID when searching:
```json
GET /my-nlp-index/_search
{
"_source": {
"excludes": [
"passage_embedding"
]
},
"query": {
"neural": {
"passage_embedding": {
"query_text": "Hi world",
"k": 100
}
}
}
}
```
{% include copy-curl.html %}
The response contains both documents:
```json
{
"took" : 41,
"timed_out" : false,
"_shards" : {
"total" : 1,
"successful" : 1,
"skipped" : 0,
"failed" : 0
},
"hits" : {
"total" : {
"value" : 2,
"relation" : "eq"
},
"max_score" : 1.22762,
"hits" : [
{
"_index" : "my-nlp-index",
"_id" : "2",
"_score" : 1.22762,
"_source" : {
"passage_text" : "Hi planet",
"id" : "s2"
}
},
{
"_index" : "my-nlp-index",
"_id" : "1",
"_score" : 1.2251667,
"_source" : {
"passage_text" : "Hello world",
"id" : "s1"
}
}
]
}
}
```