[role="xpack"] [testenv="basic"] [[put-inference]] === Create {infer} trained model API [subs="attributes"] ++++ Create {infer} trained model ++++ Creates an {infer} trained model. experimental[] [[ml-put-inference-request]] ==== {api-request-title} `PUT _ml/inference/` [[ml-put-inference-prereq]] ==== {api-prereq-title} If the {es} {security-features} are enabled, you must have the following built-in roles and privileges: * `machine_learning_admin` For more information, see <> and <>. [[ml-put-inference-desc]] ==== {api-description-title} The create {infer} trained model API enables you to supply a trained model that is not created by {dfanalytics}. [[ml-put-inference-path-params]] ==== {api-path-parms-title} ``:: (Required, string) include::{docdir}/ml/ml-shared.asciidoc[tag=model-id] [role="child_attributes"] [[ml-put-inference-request-body]] ==== {api-request-body-title} `compressed_definition`:: (Required, string) The compressed (GZipped and Base64 encoded) {infer} definition of the model. If `compressed_definition` is specified, then `definition` cannot be specified. //Begin definition `definition`:: (Required, object) The {infer} definition for the model. If `definition` is specified, then `compressed_definition` cannot be specified. + .Properties of `definition` [%collapsible%open] ==== //Begin preprocessors `preprocessors`:: (Optional, object) Collection of preprocessors. See <>. + .Properties of `preprocessors` [%collapsible%open] ===== //Begin frequency encoding `frequency_encoding`:: (Required, object) Defines a frequency encoding for a field. + .Properties of `frequency_encoding` [%collapsible%open] ====== `feature_name`:: (Required, string) The name of the resulting feature. `field`:: (Required, string) The field name to encode. `frequency_map`:: (Required, object map of string:double) Object that maps the field value to the frequency encoded value. ====== //End frequency encoding //Begin one hot encoding `one_hot_encoding`:: (Required, object) Defines a one hot encoding map for a field. + .Properties of `one_hot_encoding` [%collapsible%open] ====== `field`:: (Required, string) The field name to encode. `hot_map`:: (Required, object map of strings) String map of "field_value: one_hot_column_name". ====== //End one hot encoding //Begin target mean encoding `target_mean_encoding`:: (Required, object) Defines a target mean encoding for a field. + .Properties of `target_mean_encoding` [%collapsible%open] ====== `default_value`::: (Required, double) The feature value if the field value is not in the `target_map`. `feature_name`::: (Required, string) The name of the resulting feature. `field`::: (Required, string) The field name to encode. `target_map`::: (Required, object map of string:double) Object that maps the field value to the target mean value. ====== //End target mean encoding ===== //End preprocessors //Begin trained model `trained_model`:: (Required, object) The definition of the trained model. + .Properties of `trained_model` [%collapsible%open] ===== //Begin tree `tree`:: (Required, object) The definition for a binary decision tree. + .Properties of `tree` [%collapsible%open] ====== `classification_labels`::: (Optional, string) An array of classification labels (used for `classification`). `feature_names`::: (Required, string) Features expected by the tree, in their expected order. `target_type`::: (Required, string) String indicating the model target type; `regression` or `classification`. `tree_structure`::: (Required, object) An array of `tree_node` objects. The nodes must be in ordinal order by their `tree_node.node_index` value. ====== //End tree //Begin tree node `tree_node`:: (Required, object) The definition of a node in a tree. + -- There are two major types of nodes: leaf nodes and not-leaf nodes. * Leaf nodes only need `node_index` and `leaf_value` defined. * All other nodes need `split_feature`, `left_child`, `right_child`, `threshold`, `decision_type`, and `default_left` defined. -- + .Properties of `tree_node` [%collapsible%open] ====== `decision_type`:: (Optional, string) Indicates the positive value (in other words, when to choose the left node) decision type. Supported `lt`, `lte`, `gt`, `gte`. Defaults to `lte`. `default_left`:: (Optional, boolean) Indicates whether to default to the left when the feature is missing. Defaults to `true`. `leaf_value`:: (Optional, double) The leaf value of the of the node, if the value is a leaf (in other words, no children). `left_child`:: (Optional, integer) The index of the left child. `node_index`:: (Integer) The index of the current node. `right_child`:: (Optional, integer) The index of the right child. `split_feature`:: (Optional, integer) The index of the feature value in the feature array. `split_gain`:: (Optional, double) The information gain from the split. `threshold`:: (Optional, double) The decision threshold with which to compare the feature value. ====== //End tree node //Begin ensemble `ensemble`:: (Optional, object) The definition for an ensemble model. See <>. + .Properties of `ensemble` [%collapsible%open] ====== //Begin aggregate output `aggregate_output`:: (Required, object) An aggregated output object that defines how to aggregate the outputs of the `trained_models`. Supported objects are `weighted_mode`, `weighted_sum`, and `logistic_regression`. See <>. + .Properties of `aggregate_output` [%collapsible%open] ======= //Begin logistic regression `logistic_regression`:: (Optional, object) This `aggregated_output` type works with binary classification (classification for values [0, 1]). It multiplies the outputs (in the case of the `ensemble` model, the inference model values) by the supplied `weights`. The resulting vector is summed and passed to a https://en.wikipedia.org/wiki/Sigmoid_function[`sigmoid` function]. The result of the `sigmoid` function is considered the probability of class 1 (`P_1`), consequently, the probability of class 0 is `1 - P_1`. The class with the highest probability (either 0 or 1) is then returned. For more information about logistic regression, see https://en.wikipedia.org/wiki/Logistic_regression[this wiki article]. + .Properties of `logistic_regression` [%collapsible%open] ======== `weights`::: (Required, double) The weights to multiply by the input values (the inference values of the trained models). ======== //End logistic regression //Begin weighted sum `weighted_sum`:: (Optional, object) This `aggregated_output` type works with regression. The weighted sum of the input values. + .Properties of `weighted_sum` [%collapsible%open] ======== `weights`::: (Required, double) The weights to multiply by the input values (the inference values of the trained models). ======== //End weighted sum //Begin weighted mode `weighted_mode`:: (Optional, object) This `aggregated_output` type works with regression or classification. It takes a weighted vote of the input values. The most common input value (taking the weights into account) is returned. + .Properties of `weighted_mode` [%collapsible%open] ======== `weights`::: (Required, double) The weights to multiply by the input values (the inference values of the trained models). ======== //End weighted mode ======= //End aggregate output `classification_labels`:: (Optional, string) An array of classification labels. `feature_names`:: (Optional, string) Features expected by the ensemble, in their expected order. `target_type`:: (Required, string) String indicating the model target type; `regression` or `classification.` `trained_models`:: (Required, object) An array of `trained_model` objects. Supported trained models are `tree` and `ensemble`. ====== //End ensemble ===== //End trained model ==== //End definition `description`:: (Optional, string) A human-readable description of the {infer} trained model. //Begin inference_config `inference_config`:: (Required, object) The default configuration for inference. This can be either a `regression` or `classification` configuration. It must match the underlying `definition.trained_model`'s `target_type`. + .Properties of `inference_config` [%collapsible%open] ==== `regression`::: (Optional, object) Regression configuration for inference. + .Properties of regression inference [%collapsible%open] ===== `num_top_feature_importance_values`:::: (Optional, integer) include::{docdir}/ml/ml-shared.asciidoc[tag=inference-config-regression-num-top-feature-importance-values] `results_field`:::: (Optional, string) include::{docdir}/ml/ml-shared.asciidoc[tag=inference-config-results-field] ===== `classification`::: (Optional, object) Classification configuration for inference. + .Properties of classification inference [%collapsible%open] ===== `num_top_classes`:::: (Optional, integer) include::{docdir}/ml/ml-shared.asciidoc[tag=inference-config-classification-num-top-classes] `num_top_feature_importance_values`:::: (Optional, integer) include::{docdir}/ml/ml-shared.asciidoc[tag=inference-config-classification-num-top-feature-importance-values] `results_field`:::: (Optional, string) include::{docdir}/ml/ml-shared.asciidoc[tag=inference-config-results-field] `top_classes_results_field`:::: (Optional, string) include::{docdir}/ml/ml-shared.asciidoc[tag=inference-config-classification-top-classes-results-field] ===== ==== //End of inference_config //Begin input `input`:: (Required, object) The input field names for the model definition. + .Properties of `input` [%collapsible%open] ==== `field_names`::: (Required, string) An array of input field names for the model. ==== //End input `metadata`:: (Optional, object) An object map that contains metadata about the model. `tags`:: (Optional, string) An array of tags to organize the model. [[ml-put-inference-example]] ==== {api-examples-title} [[ml-put-inference-preprocessor-example]] ===== Preprocessor examples The example below shows a `frequency_encoding` preprocessor object: [source,js] ---------------------------------- { "frequency_encoding":{ "field":"FlightDelayType", "feature_name":"FlightDelayType_frequency", "frequency_map":{ "Carrier Delay":0.6007414737092798, "NAS Delay":0.6007414737092798, "Weather Delay":0.024573576178086153, "Security Delay":0.02476631010889467, "No Delay":0.6007414737092798, "Late Aircraft Delay":0.6007414737092798 } } } ---------------------------------- //NOTCONSOLE The next example shows a `one_hot_encoding` preprocessor object: [source,js] ---------------------------------- { "one_hot_encoding":{ "field":"FlightDelayType", "hot_map":{ "Carrier Delay":"FlightDelayType_Carrier Delay", "NAS Delay":"FlightDelayType_NAS Delay", "No Delay":"FlightDelayType_No Delay", "Late Aircraft Delay":"FlightDelayType_Late Aircraft Delay" } } } ---------------------------------- //NOTCONSOLE This example shows a `target_mean_encoding` preprocessor object: [source,js] ---------------------------------- { "target_mean_encoding":{ "field":"FlightDelayType", "feature_name":"FlightDelayType_targetmean", "target_map":{ "Carrier Delay":39.97465788139886, "NAS Delay":39.97465788139886, "Security Delay":203.171206225681, "Weather Delay":187.64705882352948, "No Delay":39.97465788139886, "Late Aircraft Delay":39.97465788139886 }, "default_value":158.17995752420433 } } ---------------------------------- //NOTCONSOLE [[ml-put-inference-model-example]] ===== Model examples The first example shows a `trained_model` object: [source,js] ---------------------------------- { "tree":{ "feature_names":[ "DistanceKilometers", "FlightTimeMin", "FlightDelayType_NAS Delay", "Origin_targetmean", "DestRegion_targetmean", "DestCityName_targetmean", "OriginAirportID_targetmean", "OriginCityName_frequency", "DistanceMiles", "FlightDelayType_Late Aircraft Delay" ], "tree_structure":[ { "decision_type":"lt", "threshold":9069.33437193022, "split_feature":0, "split_gain":4112.094574306927, "node_index":0, "default_left":true, "left_child":1, "right_child":2 }, ... { "node_index":9, "leaf_value":-27.68987349695448 }, ... ], "target_type":"regression" } } ---------------------------------- //NOTCONSOLE The following example shows an `ensemble` model object: [source,js] ---------------------------------- "ensemble":{ "feature_names":[ ... ], "trained_models":[ { "tree":{ "feature_names":[], "tree_structure":[ { "decision_type":"lte", "node_index":0, "leaf_value":47.64069875778043, "default_left":false } ], "target_type":"regression" } }, ... ], "aggregate_output":{ "weighted_sum":{ "weights":[ ... ] } }, "target_type":"regression" } ---------------------------------- //NOTCONSOLE [[ml-put-inference-aggregated-output-example]] ===== Aggregated output example Example of a `logistic_regression` object: [source,js] ---------------------------------- "aggregate_output" : { "logistic_regression" : { "weights" : [2.0, 1.0, .5, -1.0, 5.0, 1.0, 1.0] } } ---------------------------------- //NOTCONSOLE Example of a `weighted_sum` object: [source,js] ---------------------------------- "aggregate_output" : { "weighted_sum" : { "weights" : [1.0, -1.0, .5, 1.0, 5.0] } } ---------------------------------- //NOTCONSOLE Example of a `weighted_mode` object: [source,js] ---------------------------------- "aggregate_output" : { "weighted_mode" : { "weights" : [1.0, 1.0, 1.0, 1.0, 1.0] } } ---------------------------------- //NOTCONSOLE [[ml-put-inference-json-schema]] ===== {infer-cap} JSON schema For the full JSON schema of model {infer}, https://github.com/elastic/ml-json-schemas[click here].