merlin.models.tf.ItemRetrievalScorer#

class merlin.models.tf.ItemRetrievalScorer(*args, **kwargs)[source]#

Bases: merlin.models.tf.core.base.Block

Block for ItemRetrieval, which expects query/user and item embeddings as input and uses dot product to score the positive item (inputs[“item”]) and also sampled negative items (during training). :param samplers: List of item samplers that provide negative samples when training=True :type samplers: List[ItemSampler], optional :param sampling_downscore_false_negatives: Identify false negatives (sampled item ids equal to the positive item and downscore them

to the sampling_downscore_false_negatives_value), by default True

Parameters

sampling_downscore_false_negatives_value (int, optional) – Value to be used to downscore false negatives when sampling_downscore_false_negatives=True, by default np.finfo(np.float32).min / 100.0
item_id_feature_name (str) – Name of the column containing the item ids Defaults to item_id
query_name (str) – Identify query tower for query/user embeddings, by default ‘query’
item_name (str) – Identify item tower for item embeddings, by default’item’
cache_query (bool) – Add query embeddings to the context block, by default False
sampled_softmax_mode (bool) – Use sampled softmax for scoring, by default False
store_negative_ids (bool) – Returns negative items ids as part of the output, by default False

__init__(samplers: Sequence[merlin.models.tf.blocks.sampling.base.ItemSampler] = (), sampling_downscore_false_negatives=True, sampling_downscore_false_negatives_value: float = - 655.04, item_id_feature_name: str = 'item_id', item_domain: str = 'item_id', query_name: str = 'query', item_name: str = 'item', cache_query: bool = False, sampled_softmax_mode: bool = False, store_negative_ids: bool = False, **kwargs)[source]#

Methods

`__init__`([samplers, ...])
`add_loss`(losses, **kwargs)	Add loss tensor(s), potentially dependent on layer inputs.
`add_metric`(value[, name])	Adds metric tensor to the layer.
`add_update`(updates)	Add update op(s), potentially dependent on layer inputs.
`add_variable`(args, *kwargs)	Deprecated, do NOT use! Alias for add_weight.
`add_weight`([name, shape, dtype, ...])	Adds a new variable to the layer.
`as_tabular`([name])
`build`(input_shapes)
`build_from_config`(config)
`call`(inputs[, training, testing])	Based on the user/query embedding (inputs[self.query_name]), uses dot product to score
`call_outputs`(outputs[, features, training, ...])	Based on the user/query embedding (inputs[self.query_name]), uses dot product to score
`check_schema`([schema])
`compute_mask`(inputs[, mask])	Computes an output mask tensor.
`compute_output_shape`(input_shape)	Computes the output shape of the layer.
`compute_output_signature`(input_signature)	Compute the output tensor signature of the layer based on the inputs.
`connect`(*block[, block_name, context])	Connect the block to other blocks sequentially.
`connect_branch`(*branches[, add_rest, post, ...])	Connect the block to one or multiple branches.
`connect_debug_block`([append])	Connect the block to a debug block.
`connect_with_residual`(block[, activation])	Connect the block to other blocks sequentially with a residual connection.
`connect_with_shortcut`(block[, ...])	Connect the block to other blocks sequentially with a shortcut connection.
`copy`()
`count_params`()	Count the total number of scalars composing the weights.
`finalize_state`()	Finalizes the layers state after updating layer weights.
`from_config`(config)
`from_layer`(layer)
`get_build_config`()
`get_config`()
`get_input_at`(node_index)	Retrieves the input tensor(s) of a layer at a given node.
`get_input_mask_at`(node_index)	Retrieves the input mask tensor(s) of a layer at a given node.
`get_input_shape_at`(node_index)	Retrieves the input shape(s) of a layer at a given node.
`get_item_ids_from_inputs`(inputs)
`get_output_at`(node_index)	Retrieves the output tensor(s) of a layer at a given node.
`get_output_mask_at`(node_index)	Retrieves the output mask tensor(s) of a layer at a given node.
`get_output_shape_at`(node_index)	Retrieves the output shape(s) of a layer at a given node.
`get_padding_mask_from_item_id`(inputs[, ...])
`get_weights`()	Returns the current weights of the layer, as NumPy arrays.
`parse`(*block)
`parse_block`(input)
`prepare`([block, post, aggregation])	Transform the inputs of this block.
`register_features`(feature_shapes)
`repeat`([num])	Repeat the block num times.
`repeat_in_parallel`([num, prefix, names, ...])	Repeat the block num times in parallel.
`select_by_name`(name)
`select_by_tag`(tags)
`set_required_features`()
`set_schema`([schema])
`set_weights`(weights)	Sets the weights of the layer, from NumPy arrays.
`with_name_scope`(method)	Decorator to automatically enter the module name scope.

Attributes

`REQUIRES_SCHEMA`
`activity_regularizer`	Optional regularizer function for the output of this layer.
`compute_dtype`	The dtype of the layer's computations.
`context`
`dtype`	The dtype of the layer weights.
`dtype_policy`	The dtype policy associated with this layer.
`dynamic`	Whether the layer is dynamic (eager-only); set in the constructor.
`has_schema`
`inbound_nodes`	Return Functional API nodes upstream of this layer.
`input`	Retrieves the input tensor(s) of a layer.
`input_mask`	Retrieves the input mask tensor(s) of a layer.
`input_shape`	Retrieves the input shape(s) of a layer.
`input_spec`	InputSpec instance(s) describing the input format for this layer.
`losses`	List of losses added using the add_loss() API.
`metrics`	List of metrics added using the add_metric() API.
`name`	Name of the layer (string), set in the constructor.
`name_scope`	Returns a tf.name_scope instance for this class.
`non_trainable_variables`
`non_trainable_weights`	List of all non-trainable weights tracked by this layer.
`outbound_nodes`	Return Functional API nodes downstream of this layer.
`output`	Retrieves the output tensor(s) of a layer.
`output_mask`	Retrieves the output mask tensor(s) of a layer.
`output_shape`	Retrieves the output shape(s) of a layer.
`registry`
`schema`
`stateful`
`submodules`	Sequence of all sub-modules.
`supports_masking`	Whether this layer supports computing a mask using compute_mask.
`trainable`
`trainable_variables`
`trainable_weights`	List of all trainable weights tracked by this layer.
`updates`
`variable_dtype`	Alias of Layer.dtype, the dtype of the weights.
`variables`	Returns the list of all layer variables/weights.
`weights`	Returns the list of all layer variables/weights.

build(input_shapes)[source]#

call(inputs: Union[tensorflow.python.framework.ops.Tensor, Dict[str, tensorflow.python.framework.ops.Tensor]], training: bool = True, testing: bool = False, **kwargs) → Union[tensorflow.python.framework.ops.Tensor, Dict[str, tensorflow.python.framework.ops.Tensor]][source]#

Based on the user/query embedding (inputs[self.query_name]), uses dot product to score: the positive item (inputs[“item”]). For the sampled-softmax mode, logits are computed by multiplying the query vector and the item embeddings matrix (self.context.get_embedding(self.item_domain))

Parameters

inputs (Union[tf.Tensor, TabularData]) – Dict with the query and item embeddings (e.g. {“query”: <emb>}, “item”: <emb>}), where embeddings are 2D tensors (batch size, embedding size)
training (bool, optional) – Flag that indicates whether in training mode, by default True

Returns

2D Tensor with the scores for the positive items, If training=True, return the original inputs

Return type

tf.Tensor

call_outputs(outputs: merlin.models.tf.core.base.PredictionOutput, features: Dict[str, tensorflow.python.framework.ops.Tensor] = None, training=True, testing=False, **kwargs) → PredictionOutput[source]#

Based on the user/query embedding (inputs[self.query_name]), uses dot product to score: the positive item and also sampled negative items (during training).

Parameters

inputs (TabularData) – Dict with the query and item embeddings (e.g. {“query”: <emb>}, “item”: <emb>}), where embeddings are 2D tensors (batch size, embedding size)
training (bool, optional) – Flag that indicates whether in training mode, by default True

Returns

all_scores: 2D Tensor with the scores for the positive items and, if training=True, for the negative sampled items too. Return tensor is 2D (batch size, 1 + #negatives)

Return type

[tf.Tensor,tf.Tensor]

set_required_features()[source]#

get_config()[source]#

classmethod from_config(config)[source]#