Briefly, this error occurs when Elasticsearch is expecting a specific field in the request body, but it’s not provided. This could be due to incorrect or incomplete data input. To resolve this, ensure that all required fields are included in your request. Check your data input against the Elasticsearch documentation for the specific operation you’re trying to perform. Also, validate your data to ensure it’s in the correct format before sending the request. If the field is optional and not needed, you can adjust your Elasticsearch settings to ignore missing fields.
This guide will help you check for common problems that cause the log ” Missing required field [ ” to appear. To understand the issues related to this log, read the explanation below about the following Elasticsearch concepts: aggregations, search.
Aggregations in Elasticsearch
Definition
The aggregations framework is a powerful tool built in every Elasticsearch deployment. In Elasticsearch, an aggregation is a collection or the gathering of related things together. The aggregation framework collects data based on the documents that match a search request which helps in building summaries of the data. With aggregations you can not only search your data, but also take it a step further and extract analytical information.
Aggregations are used all over the place in Kibana: dashboards, APM app, Machine Learning app and so on. Aggregations are also heavily used in common search use cases, such as an e-Commerce website. In those use cases search results usually come with a set of filters that take into account only the scope of the result set of your search. The user is then given the option to filter even further by, for example, product category, color, range of price and so on. Those filter options usually come with a metric indication to give the user an idea of, for example, how many items per category their search results contain.
This kind of feature is only possible by using the aggregations framework.
Other examples of uses of the aggregations framework include the following:
- Average load time of a website
- Most valuable customers based on transaction volume
- Histogram showing some metric (quantity, average, sum, …) for events occurred in dynamically generated time periods
- Quantity of products in each product category
Below are the different types of aggregations:
Types of aggregations
- Bucket aggregations: Aggregations that group documents into buckets, also called bins, based on field values, ranges, or other criteria in the document. When the aggregation is performed, the documents are placed in the respective bucket(s). This way you can divide a set of invoices into several buckets, one for each customer, system logs can be divided into “error”,”warning” and “info”, or CPU performance data divided into hourly buckets. The output consists of a list of buckets, each with a key and a count of documents. Here are some examples of bucket aggregations: Histogram Aggregation, Range Aggregation, Terms Aggregation, Filter(s) Aggregations, Geo Distance Aggregation and IP Range Aggregation.
- Metric aggregations: Aggregations that calculate metrics, such as a sum or average, from field values. Mainly refers to the mathematical calculations performed across a set of documents, usually based on the values of a numerical field present in the document, such as COUNT, SUM, MIN, MAX, AVERAGE etc. Metrics may be carried out at top level, but are often more useful as a sub aggregation to calculate values for a bucket aggregation.
- Pipeline aggregations: Aggregations that take input from other aggregations instead of documents or fields. These aggregations allow you to aggregate based on the result of another aggregation rather than from document sets. Typically this aggregation is used to find the average number of documents in a bucket, or to sort buckets based upon a metric produced by a metric aggregation.
Aggregation syntax
You request the cluster to run aggregations by adding an aggregations (or aggs for short) parameter in your search request. You can ask for more than one aggregation per request. You can even ask for sub-aggregations of a bucket aggregation. The following example shows a request that asks for the sum of the quantities of products, grouped by country.
In the example below, let’s say the use case is an e-Commerce website that acts as a marketplace, meaning they actually allow third party vendors to advertise products in their website, so in this example we want to know how many units of each product there are in each country, and we do that by summing the stock of each third party vendor. This would give us a global stock.
POST products/_search { "size": 0, "aggs": { "by-country": { "terms": { "field": "country" }, "aggs": { "stock": { "sum": { "field": "qty" } } } } } }
Some things to notice in the example above:
- You can use aggregations and aggs interchangeably. Every aggregation (or sub aggregation) has a name (by-country and stock, in this case).
- We have set the size of the results to 0, which means we’re not getting any hits in the response. That’s not uncommon at all and is even recommended.
- In the example we only used the terms (bucket aggregation) and sum (metric aggregation) aggregation types, but the aggregations framework offers many more.
- We made use of a sub-aggregation. Notice the by-country aggregation actually creates buckets (groups) of results and then the stock aggregation gives a metric for each bucket. You can nest as many bucket aggregations as you want, before we finally (and optionally) run a metric aggregation on it.
Nesting aggregations
It is possible to nest aggregations inside one another (nothing to do with nested fields), so as to divide the buckets into sub buckets, or to calculate metrics from the sub buckets. The below aggregation will separate out all exam results by gender of the pupil and then calculate the average results for each gender. In this case, the important thing to understand is that the second aggregation will be calculated on the individual set of the bucket rather than the document set as a whole.
POST exam_results*/_search { "size": 0, "aggs": { "genders": { "terms": { "field": "gender" }, "aggs": { "avg_grade": { "avg": { "field": "grades" } } } } } }
Aggregation performance
Aggregations are typically carried out in RAM memory, and require a different document access structure than a search query that is obtained from the inverted index, so it is important to consider the implication of performance when constructing your aggregations. The most important considerations are:
Number of buckets
This would be controlled by the “size” parameter in a terms aggregation, or the “calendar interval” in a date histogram. Bear in mind that where you have bucket aggregations nested at more than one level, then the total number of buckets will be multiplied for each level of aggregation.
Number of documents
When running an aggregation,it is preferable (if possible) to adjust the query so that your aggregation is only performed on a restricted set of those documents that you are interested in, instead of using a match_all query. This will reduce the memory required to run the aggregation.
Fielddata
Aggregations as a rule should always be run on keyword type fields, not analysed text. It is possible to run on analyzed text by using the mapping setting “fielddata”:”true” but this is highly memory intensive and should be avoided if possible.
Overview
Search refers to the searching of documents in an index or multiple indices. The simple search is just a GET API request to the _search endpoint. The search query can either be provided in query string or through a request body.
Examples
When looking for any documents in this index, if search parameters are not provided, every document is a hit and by default 10 hits will be returned.
GET my_documents/_search
A JSON object is returned in response to a search query. A 200 response code means the request was completed successfully.
{ "took" : 1, "timed_out" : false, "_shards" : { "total" : 2, "successful" : 2, "failed" : 0 }, "hits" : { "total" : 2, "max_score" : 1.0, "hits" : [ ... ] } }
Notes and good things to know
- Distributed search is challenging and every shard of the index needs to be searched for hits, and then those hits are combined into a single sorted list as a final result.
- There are two phases of search: the query phase and the fetch phase.
- In the query phase, the query is executed on each shard locally and top hits are returned to the coordinating node. The coordinating node merges the results and creates a global sorted list.
- In the fetch phase, the coordinating node brings the actual documents for those hit IDs and returns them to the requesting client.
- A coordinating node needs enough memory and CPU in order to handle the fetch phase.
Log Context
Log “Missing required field [” class name is DerivativePipelineAggregationBuilder.java. We extracted the following from Elasticsearch source code for those seeking an in-depth context :
"Unexpected token " + token + " in [" + pipelineAggregatorName + "]."); } } if (bucketsPaths == null) { throw new ParsingException(parser.getTokenLocation(); "Missing required field [" + BUCKETS_PATH_FIELD.getPreferredName() + "] for derivative aggregation [" + pipelineAggregatorName + "]"); } DerivativePipelineAggregationBuilder factory = new DerivativePipelineAggregationBuilder(pipelineAggregatorName; bucketsPaths[0]);
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