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Options for Exporting Data from Phoenix

Connect to Phoenix

Before using any of the methods below, instantiate a Client. You’ll need to set the following environment variables:
If you’re self-hosting Phoenix, ignore the client headers and change the collector endpoint to your endpoint.

Downloading all Spans as a Dataframe

If you prefer to handle your filtering locally, you can also download all spans as a dataframe using the get_spans_dataframe() method:

Running Span Queries

You can query for data using our query DSL (domain specific language).
This Query DSL is the same as what is used by the filter bar in the dashboard. It can be helpful to form your query string in the Phoenix dashboard for more immediate feedback, before moving it to code.
Below is an example of how to pull all retriever spans and select the input value. The output of this query is a DataFrame that contains the input values for all retriever spans.
DataFrame Index By default, the result DataFrame is indexed by span_id, and if .explode() is used, the index from the exploded list is added to create a multi-index on the result DataFrame. For the special retrieval.documents span attribute, the added index is renamed as document_position.

How to Specify a Time Range

By default, all queries will collect all spans that are in your Phoenix instance. If you’d like to focus on most recent spans, you can pull spans based on time frames using start_time and end_time.

How to Specify a Project

By default all queries are executed against the default project or the project set via the PHOENIX_PROJECT_NAME environment variable. If you choose to pull from a different project, all methods on the Client have an optional parameter named project_name

Querying for Retrieved Documents

Let’s say we want to extract the retrieved documents into a DataFrame that looks something like the table below, where input denotes the query for the retriever, reference denotes the content of each document, and document_position denotes the (zero-based) index in each span’s list of retrieved documents. Note that this DataFrame can be used directly as input for the Retrieval (RAG) Relevance evaluations. We can accomplish this with a simple query as follows:

How to Explode Attributes

In addition to the document content, if we also want to explode the document score, we can simply add the document.score attribute to the .explode() method alongside document.content as follows. Keyword arguments are necessary to name the output columns, and in this example we name the output columns as reference and score. (Python’s double-asterisk unpacking idiom can be used to specify arbitrary output names containing spaces or symbols. See here for an example.)

How to Apply Filters

The .where() method accepts a string of valid Python boolean expression. The expression can be arbitrarily complex, but restrictions apply, e.g. making function calls are generally disallowed. Below is a conjunction filtering also on whether the input value contains the string 'programming'.

Filtering Spans by Evaluation Results

Filtering spans by evaluation results, e.g. score or label, can be done via a special syntax. The name of the evaluation is specified as an indexer on the special keyword evals. The example below filters for spans with the incorrect label on their correctness evaluations. (See here for how to compute evaluations for traces, and here for how to ingest those results back to Phoenix.)

Filtering on Metadata

metadata is an attribute that is a dictionary and it can be filtered like a dictionary.

Filtering for Substring

Note that Python strings do not have a contain method, and substring search is done with the in operator.

Filtering for No Evaluations

Get spans that do not have an evaluation attached yet

How to Apply Filters (UI)

You can also use Python boolean expressions to filter spans in the Phoenix UI. These expressions can be entered directly into the search bar above your experiment runs, allowing you to apply complex conditions involving span attributes. Any expressions that work with the .where() method above can also be used in the UI.

How to Extract Attributes

Span attributes can be selected by simply listing them inside .select() method.

Renaming Output Columns

Keyword-argument style can be used to rename the columns in the dataframe. The example below returns two columns named input and output instead of the original names of the attributes.

Arbitrary Output Column Names

If arbitrary output names are desired, e.g. names with spaces and symbols, we can leverage Python’s double-asterisk idiom for unpacking a dictionary, as shown below.

Advanced Usage

Concatenating

The document contents can also be concatenated together. The query below concatenates the list of document.content with (double newlines), which is the default separator. Keyword arguments are necessary to name the output columns, and in this example we name the output column as reference. (Python’s double-asterisk unpacking idiom can be used to specify arbitrary output names containing spaces or symbols. See here for an example.)

Special Separators

If a different separator is desired, say \n************, it can be specified as follows.

Using Parent ID as Index

This is useful for joining a span to its parent span. To do that we would first index the child span by selecting its parent ID and renaming it as span_id. This works because span_id is a special column name: whichever column having that name will become the index of the output DataFrame.

Joining a Span to Its Parent

To do this, provide two queries to Phoenix and join the resulting dataframes with pandas.

How to use Data for Evaluation

Extract the Input and Output from LLM Spans

To learn more about extracting span attributes, see How to Extract Attributes.

Retrieval (RAG) Relevance Evaluations

To extract the dataframe input for Retrieval (RAG) Relevance evaluations, apply the query described in Querying for Retrieved Documents.

Q&A on Retrieved Data Evaluations

To extract the dataframe input to the Q&A on Retrieved Data evaluations, use the following query which applies techniques described in the Advanced Usage section.
The output DataFrame would look something like the one below. The input contains the question, the output column contains the answer, and the reference column contains a concatenation of all the retrieved documents.