Command Line Interface
Commands¶
Ludwig provides several functions through its command line interface.
Mode | Description |
---|---|
train |
Trains a model |
predict |
Predicts using a pretrained model |
evaluate |
Evaluate a pretrained model's performance |
experiment |
Runs a full experiment training a model and evaluating it |
hyperopt |
Perform hyperparameter optimization |
serve |
Serves a pretrained model |
visualize |
Visualizes experiment results |
init_config |
Initialize a user config from a dataset and targets |
render_config |
Renders the fully populated config with all defaults set |
collect_summary |
Prints names of weights and layers activations to use with other collect commands |
collect_weights |
Collects tensors containing a pretrained model weights |
collect_activations |
Collects tensors for each datapoint using a pretrained model |
export_torchscript |
Exports Ludwig models to Torchscript |
export_neuropod |
Exports Ludwig models to Neuropod |
export_mlflow |
Exports Ludwig models to MLflow |
preprocess |
Preprocess data and saves it into HDF5 and JSON format |
synthesize_dataset |
Creates synthetic data for testing purposes |
These are described in detail below.
train¶
Train a model from your data.
ludwig train [options]
or with:
python -m ludwig.train [options]
from within Ludwig's main directory.
These are the available arguments:
usage: ludwig train [options]
This script trains a model
optional arguments:
-h, --help show this help message and exit
--output_directory OUTPUT_DIRECTORY
directory that contains the results
--experiment_name EXPERIMENT_NAME
experiment name
--model_name MODEL_NAME
name for the model
--dataset DATASET input data file path. If it has a split column, it
will be used for splitting (0: train, 1: validation,
2: test), otherwise the dataset will be randomly split
--training_set TRAINING_SET
input train data file path
--validation_set VALIDATION_SET
input validation data file path
--test_set TEST_SET input test data file path
--training_set_metadata TRAINING_SET_METADATA
input metadata JSON file path. An intermediate
preprocessed containing the mappings of the input
file created the first time a file is used, in the
same directory with the same name and a .json
extension
--data_format {auto,csv,excel,feather,fwf,hdf5,htmltables,json,jsonl,parquet,pickle,sas,spss,stata,tsv}
format of the input data
-sspi, --skip_save_processed_input
skips saving intermediate HDF5 and JSON files
-c CONFIG, --config CONFIG
Path to the YAML file containing the model configuration
-cs CONFIG_STR, --config_str CONFIG_STRING
JSON or YAML serialized string of the model configuration. Ignores --config
-mlp MODEL_LOAD_PATH, --model_load_path MODEL_LOAD_PATH
path of a pretrained model to load as initialization
-mrp MODEL_RESUME_PATH, --model_resume_path MODEL_RESUME_PATH
path of the model directory to resume training of
-sstd, --skip_save_training_description
disables saving the description JSON file
-ssts, --skip_save_training_statistics
disables saving training statistics JSON file
-ssm, --skip_save_model
disables saving weights each time the model improves.
By default Ludwig saves weights after each epoch the
validation metric improves, but if the model is really
big that can be time consuming. If you do not want to
keep the weights and just find out what performance
can a model get with a set of hyperparameters, use
this parameter to skip it
-ssp, --skip_save_progress
disables saving weights after each epoch. By default
ludwig saves weights after each epoch for enabling
resuming of training, but if the model is really big
that can be time consuming and will save twice as much
space, use this parameter to skip it
-ssl, --skip_save_log
disables saving TensorBoard logs. By default Ludwig
saves logs for the TensorBoard, but if it is not
needed turning it off can slightly increase the
overall speed
-rs RANDOM_SEED, --random_seed RANDOM_SEED
a random seed that is going to be used anywhere there
is a call to a random number generator: data
splitting, parameter initialization and training set
shuffling
-g GPUS [GPUS ...], --gpus GPUS [GPUS ...]
list of gpus to use
-gml GPU_MEMORY_LIMIT, --gpu_memory_limit GPU_MEMORY_LIMIT
maximum memory in MB to allocate per GPU device
-dpt, --disable_parallel_threads
disable Torch from using multithreading for
reproducibility
-b BACKEND, --backend BACKEND
specifies backend to use for parallel / distributed execution,
defaults to local execution or Horovod if called using horovodrun
When Ludwig trains a model it creates two intermediate files, one HDF5 and one JSON. The HDF5 file contains the data mapped to numpy ndarrays, while the JSON file contains the mappings from the values in the tensors to their original labels.
For instance, for a categorical feature with 3 possible values, the HDF5 file
will contain integers from 0 to 3 (with 0 being a <UNK>
category), while the
JSON file will contain a idx2str
list containing all tokens
([<UNK>, label_1, label_2, label_3]
), a str2idx
dictionary
({"<UNK>": 0, "label_1": 1, "label_2": 2, "label_3": 3}
) and a str2freq
dictionary ({"<UNK>": 0, "label_1": 93, "label_2": 55, "label_3": 24}
).
The reason to have those intermediate files is two-fold: on one hand, if you are going to train your model again Ludwig will try to load them instead of recomputing all tensors, which saves a considerable amount of time, and on the other hand when you want to use your model to predict, data has to be mapped to tensors in exactly the same way it was mapped during training, so you'll be required to load the JSON metadata file in the predict
command.
The first time you provide a UTF-8 encoded dataset (--dataset
), the HDF5 and JSON files are created, from the second time on Ludwig will load them instead of the dataset even if you specify the dataset (it looks in the same directory for files names in the same way but with a different extension), finally you can directly specify the HDF5 and JSON files.
As the mapping from raw data to tensors depends on the type of feature that you specify in your configuration, if you change type (for instance from sequence
to text
) you also have to redo the preprocessing, which is achieved by deleting the HDF5 and JSON files.
Alternatively you can skip saving the HDF5 and JSON files specifying --skip_save_processed_input
.
Splitting between train, validation and test set can be done in several ways. This allows for a few possible input data scenarios:
- one single UTF-8 encoded dataset file is provided (
-dataset
). In this case if the dataset contains asplit
column with values0
for training,1
for validation and2
for test, this split will be used. If you want to ignore the split column and perform a random split, use aforce_split
argument in the configuration. In the case when there is no split column, a random70-20-10
split will be performed. You can set the percentages and specify if you want stratified sampling in the configuration preprocessing section. - you can provide separate UTF-8 encoded training, validation and test sets (
--training_set
,--validation_set
,--test_set
). - the HDF5 and JSON file indications specified in the case of a single dataset file apply also in the multiple files case, with the only difference that you need to specify only one JSON file (
--train_set_metadata_json
).
The validation set is optional, but if absent the training will continue until the end of the training epochs, while when there's a validation set the default behavior is to perform early stopping after the validation measure does not improve for a certain amount of epochs. The test set is optional too.
Other optional arguments are --output_directory
, --experiment_name
and --model name
.
By default the output directory is ./results
.
That directory will contain a directory named [experiment_name]_[model_name]_0
if model name and experiment name are specified.
If the same combination of experiment and model name is used again, the integer
at the end of the name will be increased.
If neither of them is specified the directory will be named run_0
.
The directory will contain
description.json
- a file containing a description of the training process with all the information to reproduce it.training_statistics.json
- a file containing records of all measures and losses for each epoch.model
- a directory containing model hyperparameters, weights, checkpoints and logs (for TensorBoard).
The configuration can be provided either as a string (--config_str
)
or as YAML file (--config
).
Details on how to write your configuration are provided in the Configuration section.
During training Ludwig saves two sets of weights for the model, one that is the weights at the end of the epoch where the best performance on the validation measure was achieved and one that is the weights at the end of the latest epoch. The reason for keeping the second set is to be able to resume training in case the training process gets interrupted somehow.
To resume training using the latest weights and the whole history of progress so far you have to specify the --model_resume_path
argument.
You can avoid saving the latest weights and the overall progress so far by using the argument --skip_save_progress
, but you will not be able to resume it afterwards.
Another available option is to load a previously trained model as an initialization for a new training process. In this case Ludwig will start a new training process, without knowing any progress of the previous model, no training statistics, nor the number of epochs the model has been trained on so far.
It's not resuming training, just initializing training with a previously trained model with the same configuration, and it is accomplished through the --model_load_path
argument.
You can specify a random seed to be used by the python environment, python random package, numpy and Torch with the --random_seed
argument.
This is useful for reproducibility.
Be aware that due to asynchronicity in the Torch's GPU execution, when training on GPU results may not be reproducible.
You can manage which GPUs on your machine are used with the --gpus
argument, which accepts a string identical to the format of CUDA_VISIBLE_DEVICES
environment variable, namely a list of integers separated by comma.
You can also specify the maximum amount of GPU memory which will be allocated per device with --gpu_memory_limit
.
By default all of memory is allocated.
If less than all of memory is allocated, Torch will need more GPU memory it will try to increase this amount.
If parameter --backend
is set, will use the given backend for distributed processing (Horovod or Ray).
Finally the --logging_level
argument lets you set the amount of logging that you want to see during training.
Example:
ludwig train --dataset reuters-allcats.csv --config "{input_features: [{name: text, type: text, encoder: {type: parallel_cnn}}], output_features: [{name: class, type: category}]}"
predict¶
This command lets you use a previously trained model to predict on new data. You can call it with:
ludwig predict [options]
or with:
python -m ludwig.predict [options]
from within Ludwig's main directory.
These are the available arguments:
usage: ludwig predict [options]
This script loads a pretrained model and uses it to predict
optional arguments:
-h, --help show this help message and exit
--dataset DATASET input data file path
--data_format {auto,csv,excel,feather,fwf,hdf5,htmltables,json,jsonl,parquet,pickle,sas,spss,stata,tsv}
format of the input data
-s {training,validation,test,full}, --split {training,validation,test,full}
the split to test the model on
-m MODEL_PATH, --model_path MODEL_PATH
model to load
-od OUTPUT_DIRECTORY, --output_directory OUTPUT_DIRECTORY
directory that contains the results
-ssuo, --skip_save_unprocessed_output
skips saving intermediate NPY output files
-sstp, --skip_save_predictions
skips saving predictions CSV files
-bs BATCH_SIZE, --batch_size BATCH_SIZE
size of batches
-g GPUS, --gpus GPUS list of gpu to use
-gml GPU_MEMORY_LIMIT, --gpu_memory_limit GPU_MEMORY_LIMIT
maximum memory in MB to allocate per GPU device
-dpt, --disable_parallel_threads
disable Torch from using multithreading for
reproducibility
-b BACKEND, --backend BACKEND
specifies backend to use for parallel / distributed execution,
defaults to local execution or Horovod if called using horovodrun
-dbg, --debug enables debugging mode
-l {critical,error,warning,info,debug,notset}, --logging_level {critical,error,warning,info,debug,notset}
the level of logging to use
The same distinction between UTF-8 encoded dataset files and HDF5 / JSON files explained in the train section also applies here.
In either case, the JSON metadata file obtained during training is needed in order to map the new data into tensors.
If the new data contains a split column, you can specify which split to use to calculate the predictions with the --split
argument. By default it's full
which means all the splits will be used.
A model to load is needed, and you can specify its path with the --model_path
argument.
If you trained a model previously and got the results in, for instance,
./results/experiment_run_0
, you have to specify
./results/experiment_run_0/model
for using it to predict.
You can specify an output directory with the argument --output-directory
, by
default it will be ./result_0
, with increasing numbers if a directory with the same name is present.
The directory will contain a prediction CSV file and a probability CSV file for
each output feature, together with raw NPY files containing raw tensors.
You can specify not to save the raw NPY output files with the argument skip_save_unprocessed_output
.
A specific batch size for speeding up the prediction can be specified using the argument --batch_size
.
Finally the --logging_level
, --debug
, --gpus
, --gpu_memory_limit
and --disable_parallel_threads
related arguments behave exactly like described in the train command section.
Example:
ludwig predict --dataset reuters-allcats.csv --model_path results/experiment_run_0/model/
evaluate¶
This command lets you use a previously trained model to predict on new data and evaluate the performance of the prediction compared to ground truth. You can call it with:
ludwig evaluate [options]
or with:
python -m ludwig.evaluate [options]
from within Ludwig's main directory.
These are the available arguments:
usage: ludwig evaluate [options]
This script loads a pretrained model and evaluates its performance by
comparing its predictions with ground truth.
optional arguments:
-h, --help show this help message and exit
--dataset DATASET input data file path
--data_format {auto,csv,excel,feather,fwf,hdf5,htmltables,json,jsonl,parquet,pickle,sas,spss,stata,tsv}
format of the input data
-s {training,validation,test,full}, --split {training,validation,test,full}
the split to test the model on
-m MODEL_PATH, --model_path MODEL_PATH
model to load
-od OUTPUT_DIRECTORY, --output_directory OUTPUT_DIRECTORY
directory that contains the results
-ssuo, --skip_save_unprocessed_output
skips saving intermediate NPY output files
-sses, --skip_save_eval_stats
skips saving intermediate JSON eval statistics
-scp, --skip_collect_predictions
skips collecting predictions
-scos, --skip_collect_overall_stats
skips collecting overall stats
-bs BATCH_SIZE, --batch_size BATCH_SIZE
size of batches
-g GPUS, --gpus GPUS list of gpu to use
-gml GPU_MEMORY_LIMIT, --gpu_memory_limit GPU_MEMORY_LIMIT
maximum memory in MB to allocate per GPU device
-dpt, --disable_parallel_threads
disable Torch from using multithreading for
reproducibility
-b BACKEND, --backend BACKEND
specifies backend to use for parallel / distributed execution,
defaults to local execution or Horovod if called using horovodrun
-dbg, --debug enables debugging mode
-l {critical,error,warning,info,debug,notset}, --logging_level {critical,error,warning,info,debug,notset}
the level of logging to use
All parameters are the same of predict and the behavior is the same.
The only difference isthat evaluate
requires the dataset to contain also columns with the same name of output features.
This is needed because evaluate
compares the predictions produced by the model with the ground truth and will save all those statistics in a test_statistics.json
file in the result directory.
Note that the data must contain columns for each output feature with ground truth output values in order to compute the performance statistics. If you receive an error regarding a missing output feature column in your data, it means that the data does not contain the columns for each output feature to use as ground truth.
Example:
ludwig evaluate --dataset reuters-allcats.csv --model_path results/experiment_run_0/model/
experiment¶
This command combines training and evaluation into a single handy command. You
can request a k-fold cross validation run by specifying the --k_fold
parameter.
You can call it with:
ludwig experiment [options]
or with:
python -m ludwig.experiment [options]
from within Ludwig's main directory.
These are the available arguments:
usage: ludwig experiment [options]
This script trains and evaluates a model
optional arguments:
-h, --help show this help message and exit
--output_directory OUTPUT_DIRECTORY
directory that contains the results
--experiment_name EXPERIMENT_NAME
experiment name
--model_name MODEL_NAME
name for the model
--dataset DATASET input data file path. If it has a split column, it
will be used for splitting (0: train, 1: validation,
2: test), otherwise the dataset will be randomly split
--training_set TRAINING_SET
input train data file path
--validation_set VALIDATION_SET
input validation data file path
--test_set TEST_SET input test data file path
--training_set_metadata TRAINING_SET_METADATA
input metadata JSON file path. An intermediate
preprocessed containing the mappings of the input
file created the first time a file is used, in the
same directory with the same name and a .json
extension
--data_format {auto,csv,excel,feather,fwf,hdf5,htmltables,json,jsonl,parquet,pickle,sas,spss,stata,tsv}
format of the input data
-es {training,validation,test,full}, --eval_split {training,validation,test,full}
the split to evaluate the model on
-sspi, --skip_save_processed_input
skips saving intermediate HDF5 and JSON files
-ssuo, --skip_save_unprocessed_output
skips saving intermediate NPY output files
-kf K_FOLD, --k_fold K_FOLD
number of folds for a k-fold cross validation run
-skfsi, --skip_save_k_fold_split_indices
disables saving indices generated to split training
data set for the k-fold cross validation run, but if
it is not needed turning it off can slightly increase
the overall speed
-c CONFIG, --config CONFIG
Path to the YAML file containing the model configuration
-cs CONFIG_STR, --config_str CONFIG_STRING
JSON or YAML serialized string of the model configuration. Ignores --config
-mlp MODEL_LOAD_PATH, --model_load_path MODEL_LOAD_PATH
path of a pretrained model to load as initialization
-mrp MODEL_RESUME_PATH, --model_resume_path MODEL_RESUME_PATH
path of the model directory to resume training of
-sstd, --skip_save_training_description
disables saving the description JSON file
-ssts, --skip_save_training_statistics
disables saving training statistics JSON file
-sstp, --skip_save_predictions
skips saving test predictions CSV files
-sstes, --skip_save_eval_stats
skips saving eval statistics JSON file
-ssm, --skip_save_model
disables saving model weights and hyperparameters each
time the model improves. By default Ludwig saves model
weights after each epoch the validation metric
improves, but if the model is really big that can be
time consuming if you do not want to keep the weights
and just find out what performance a model can get
with a set of hyperparameters, use this parameter to
skip it,but the model will not be loadable later on
-ssp, --skip_save_progress
disables saving progress each epoch. By default Ludwig
saves weights and stats after each epoch for enabling
resuming of training, but if the model is really big
that can be time consuming and will uses twice as much
space, use this parameter to skip it, but training
cannot be resumed later on
-ssl, --skip_save_log
disables saving TensorBoard logs. By default Ludwig
saves logs for the TensorBoard, but if it is not
needed turning it off can slightly increase the
overall speed
-rs RANDOM_SEED, --random_seed RANDOM_SEED
a random seed that is going to be used anywhere there
is a call to a random number generator: data
splitting, parameter initialization and training set
shuffling
-g GPUS [GPUS ...], --gpus GPUS [GPUS ...]
list of GPUs to use
-gml GPU_MEMORY_LIMIT, --gpu_memory_limit GPU_MEMORY_LIMIT
maximum memory in MB to allocate per GPU device
-dpt, --disable_parallel_threads
disable Torch from using multithreading for
reproducibility
-b BACKEND, --backend BACKEND
specifies backend to use for parallel / distributed execution,
defaults to local execution or Horovod if called using horovodrun
-dbg, --debug enables debugging mode
-l {critical,error,warning,info,debug,notset}, --logging_level {critical,error,warning,info,debug,notset}
the level of logging to use
The parameters combine parameters from both train and test so refer to those sections for an in depth explanation. The output directory will contain the outputs both commands produce.
Example:
ludwig experiment --dataset reuters-allcats.csv --config "{input_features: [{name: text, type: text, encoder: {type: parallel_cnn}}], output_features: [{name: class, type: category}]}"
hyperopt¶
This command lets you perform an hyperparameter search with a given sampler and parameters. You can call it with:
ludwig hyperopt [options]
or with:
python -m ludwig.hyperopt [options]
from within Ludwig's main directory.
These are the available arguments:
usage: ludwig hyperopt [options]
This script searches for optimal Hyperparameters
optional arguments:
-h, --help show this help message and exit
-sshs, --skip_save_hyperopt_statistics
skips saving hyperopt statistics file
--output_directory OUTPUT_DIRECTORY
directory that contains the results
--experiment_name EXPERIMENT_NAME
experiment name
--model_name MODEL_NAME
name for the model
--dataset DATASET input data file path. If it has a split column, it
will be used for splitting (0: train, 1: validation,
2: test), otherwise the dataset will be randomly split
--training_set TRAINING_SET
input train data file path
--validation_set VALIDATION_SET
input validation data file path
--test_set TEST_SET input test data file path
--training_set_metadata TRAINING_SET_METADATA
input metadata JSON file path. An intermediate
preprocessed file containing the mappings of the input
file created the first time a file is used, in the
same directory with the same name and a .json
extension
--data_format {auto,csv,excel,feather,fwf,hdf5,htmltables,json,jsonl,parquet,pickle,sas,spss,stata,tsv}
format of the input data
-sspi, --skip_save_processed_input
skips saving intermediate HDF5 and JSON files
-c CONFIG, --config CONFIG
Path to the YAML file containing the model configuration
-cs CONFIG_STR, --config_str CONFIG_STRING
JSON or YAML serialized string of the model configuration. Ignores --config
-mlp MODEL_LOAD_PATH, --model_load_path MODEL_LOAD_PATH
path of a pretrained model to load as initialization
-mrp MODEL_RESUME_PATH, --model_resume_path MODEL_RESUME_PATH
path of the model directory to resume training of
-sstd, --skip_save_training_description
disables saving the description JSON file
-ssts, --skip_save_training_statistics
disables saving training statistics JSON file
-ssm, --skip_save_model
disables saving weights each time the model improves.
By default Ludwig saves weights after each epoch the
validation metric improves, but if the model is really
big that can be time consuming. If you do not want to
keep the weights and just find out what performance
can a model get with a set of hyperparameters, use
this parameter to skip it
-ssp, --skip_save_progress
disables saving weights after each epoch. By default
ludwig saves weights after each epoch for enabling
resuming of training, but if the model is really big
that can be time consuming and will save twice as much
space, use this parameter to skip it
-ssl, --skip_save_log
disables saving TensorBoard logs. By default Ludwig
saves logs for the TensorBoard, but if it is not
needed turning it off can slightly increase the
overall speed
-rs RANDOM_SEED, --random_seed RANDOM_SEED
a random seed that is going to be used anywhere there
is a call to a random number generator: data
splitting, parameter initialization and training set
shuffling
-g GPUS [GPUS ...], --gpus GPUS [GPUS ...]
list of gpus to use
-gml GPU_MEMORY_LIMIT, --gpu_memory_limit GPU_MEMORY_LIMIT
maximum memory in MB to allocate per GPU device
-b BACKEND, --backend BACKEND
specifies backend to use for parallel / distributed execution,
defaults to local execution or Horovod if called using horovodrun
-dbg, --debug enables debugging mode
-l {critical,error,warning,info,debug,notset}, --logging_level {critical,error,warning,info,debug,notset}
the level of logging to use
The parameters combine parameters from both train and test so refer to those sections for an in depth explanation. The output directory will contain a hyperopt_statistics.json
file that summarizes the results obtained.
In order to perform an hyperparameter optimization, the hyperopt
section needs to be provided within the configuration.
In the hyperopt
section you will be able to define what metric to optimize, what parameters, what sampler to use to optimize them and how to execute the optimization.
For details on the hyperopt
section see the detailed description in the Hyperparameter Optimization section.
serve¶
This command lets you load a pre-trained model and serve it on an http server.
You can call it with:
ludwig serve [options]
or with
python -m ludwig.serve [options]
from within Ludwig's main directory.
These are the available arguments:
usage: ludwig serve [options]
This script serves a pretrained model
optional arguments:
-h, --help show this help message and exit
-m MODEL_PATH, --model_path MODEL_PATH
model to load
-l {critical,error,warning,info,debug,notset}, --logging_level {critical,error,warning,info,debug,notset}
the level of logging to use
-p PORT, --port PORT port for server (default: 8000)
-H HOST, --host HOST host for server (default: 0.0.0.0)
The most important argument is --model_path
where you have to specify the path of the model to load.
Once running, you can make a POST request on the /predict
endpoint to run inference on the form data submitted.
Note
ludwig serve
will automatically use GPUs for serving, if avaiable to the
machine-local torch environment.
Example curl¶
File
curl http://0.0.0.0:8000/predict -X POST -F 'image_path=@path_to_image/example.png'
Text
curl http://0.0.0.0:8000/predict -X POST -F 'english_text=words to be translated'
Both Text and File
curl http://0.0.0.0:8000/predict -X POST -F 'text=mixed together with' -F 'image=@path_to_image/example.png'
Batch prediction
You can also make a POST request on the /batch_predict
endpoint to run inference on multiple samples at once.
Requests must be submitted as form data, with one of fields being dataset
: a JSON encoded string representation of the data to be predicted.
The dataset
JSON string is expected to be in the Pandas "split" format to reduce payload size. This format divides the dataset into three parts:
- columns:
List[str]
- index (optional):
List[Union[str, int]]
- data:
List[List[object]]
Additional form fields can be used to provide file resources like images that are referenced within the dataset.
Batch prediction example:
curl http://0.0.0.0:8000/batch_predict -X POST -F 'dataset={"columns": ["a", "b"], "data": [[1, 2], [3, 4]]}'
visualize¶
This command lets you visualize training and prediction statistics, alongside with comparing different models performances and predictions. You can call it with:
ludwig visualize [options]
or with:
python -m ludwig.visualize [options]
from within Ludwig's main directory.
These are the available arguments:
usage: ludwig visualize [options]
This script analyzes results and shows some nice plots.
optional arguments:
-h, --help show this help message and exit
-g GROUND_TRUTH, --ground_truth GROUND_TRUTH
ground truth file
-gm GROUND_TRUTH_METADATA, --ground_truth_metadata GROUND_TRUTH_METADATA
input metadata JSON file
-od OUTPUT_DIRECTORY, --output_directory OUTPUT_DIRECTORY
directory where to save plots.If not specified, plots
will be displayed in a window
-ff {pdf,png}, --file_format {pdf,png}
file format of output plots
-v {binary_threshold_vs_metric,calibration_1_vs_all,calibration_multiclass,compare_classifiers_multiclass_multimetric,compare_classifiers_performance_changing_k,compare_classifiers_performance_from_pred,compare_classifiers_performance_from_prob,compare_classifiers_performance_subset,compare_classifiers_predictions,compare_classifiers_predictions_distribution,compare_performance,confidence_thresholding,confidence_thresholding_2thresholds_2d,confidence_thresholding_2thresholds_3d,confidence_thresholding_data_vs_acc,confidence_thresholding_data_vs_acc_subset,confidence_thresholding_data_vs_acc_subset_per_class,confusion_matrix,frequency_vs_f1,hyperopt_hiplot,hyperopt_report,learning_curves,roc_curves,roc_curves_from_test_statistics}, --visualization {binary_threshold_vs_metric,calibration_1_vs_all,calibration_multiclass,compare_classifiers_multiclass_multimetric,compare_classifiers_performance_changing_k,compare_classifiers_performance_from_pred,compare_classifiers_performance_from_prob,compare_classifiers_performance_subset,compare_classifiers_predictions,compare_classifiers_predictions_distribution,compare_performance,confidence_thresholding,confidence_thresholding_2thresholds_2d,confidence_thresholding_2thresholds_3d,confidence_thresholding_data_vs_acc,confidence_thresholding_data_vs_acc_subset,confidence_thresholding_data_vs_acc_subset_per_class,confusion_matrix,frequency_vs_f1,hyperopt_hiplot,hyperopt_report,learning_curves,roc_curves,roc_curves_from_test_statistics}
type of visualization
-f OUTPUT_FEATURE_NAME, --output_feature_name OUTPUT_FEATURE_NAME
name of the output feature to visualize
-gts GROUND_TRUTH_SPLIT, --ground_truth_split GROUND_TRUTH_SPLIT
ground truth split - 0:train, 1:validation, 2:test
split
-tf THRESHOLD_OUTPUT_FEATURE_NAMES [THRESHOLD_OUTPUT_FEATURE_NAMES ...], --threshold_output_feature_names THRESHOLD_OUTPUT_FEATURE_NAMES [THRESHOLD_OUTPUT_FEATURE_NAMES ...]
names of output features for 2d threshold
-pred PREDICTIONS [PREDICTIONS ...], --predictions PREDICTIONS [PREDICTIONS ...]
predictions files
-prob PROBABILITIES [PROBABILITIES ...], --probabilities PROBABILITIES [PROBABILITIES ...]
probabilities files
-trs TRAINING_STATISTICS [TRAINING_STATISTICS ...], --training_statistics TRAINING_STATISTICS [TRAINING_STATISTICS ...]
training stats files
-tes TEST_STATISTICS [TEST_STATISTICS ...], --test_statistics TEST_STATISTICS [TEST_STATISTICS ...]
test stats files
-hs HYPEROPT_STATS_PATH, --hyperopt_stats_path HYPEROPT_STATS_PATH
hyperopt stats file
-mn MODEL_NAMES [MODEL_NAMES ...], --model_names MODEL_NAMES [MODEL_NAMES ...]
names of the models to use as labels
-tn TOP_N_CLASSES [TOP_N_CLASSES ...], --top_n_classes TOP_N_CLASSES [TOP_N_CLASSES ...]
number of classes to plot
-k TOP_K, --top_k TOP_K
number of elements in the ranklist to consider
-ll LABELS_LIMIT, --labels_limit LABELS_LIMIT
maximum numbers of labels. If labels in dataset are
higher than this number, "rare" label
-ss {ground_truth,predictions}, --subset {ground_truth,predictions}
type of subset filtering
-n, --normalize normalize rows in confusion matrix
-m METRICS [METRICS ...], --metrics METRICS [METRICS ...]
metrics to display in threshold_vs_metric
-pl POSITIVE_LABEL, --positive_label POSITIVE_LABEL
label of the positive class for the roc curve
-l {critical,error,warning,info,debug,notset}, --logging_level {critical,error,warning,info,debug,notset}
the level of logging to use
As the --visualization
parameters suggests, there is a vast number of visualizations readily available.
Each of them requires a different subset of this command's arguments, so they will be described one by one in the Visualizations section.
init_config¶
Initialize a user config from a dataset and targets.
usage: ludwig init_config [options]
This script initializes a valid config from a dataset.
optional arguments:
-h, --help show this help message and exit
-d DATASET, --dataset DATASET
input data file path
-t TARGET, --target TARGET
target(s) to predict as output features of the model
--time_limit_s TIME_LIMIT_S
time limit to train the model in seconds when using hyperopt
--tune_for_memory TUNE_FOR_MEMORY
refine hyperopt search space based on available host / GPU memory
--hyperopt HYPEROPT include automl hyperopt config
--random_seed RANDOM_SEED
seed for random number generators used in hyperopt to improve repeatability
--use_reference_config USE_REFERENCE_CONFIG
refine hyperopt search space by setting first search point from stored reference model config
-o OUTPUT, --output OUTPUT
output initialized YAML config path
render_config¶
Renders the fully populated config with all defaults set.
usage: ludwig render_config [options]
This script renders the full config from a user config.
optional arguments:
-h, --help show this help message and exit
-o OUTPUT, --output OUTPUT
output rendered YAML config path
collect_summary¶
This command loads a pretrained model and prints names of weights and layers activations to use with collect_weights
or collect_activations
.
ludwig collect_summary [options]
or with:
python -m ludwig.collect names [options]
from within Ludwig's main directory.
These are the available arguments:
usage: ludwig collect_summary [options]
This script loads a pretrained model and print names of weights and layer activations.
optional arguments:
-h, --help show this help message and exit
-m MODEL_PATH, --model_path MODEL_PATH
model to load
-l {critical,error,warning,info,debug,notset}, --logging_level {critical,error,warning,info,debug,notset}
the level of logging to use
collect_weights¶
This command lets you load a pre-trained model and collect the tensors with a specific name in order to save them in a NPY format. This may be useful in order to visualize the learned weights (for instance collecting embedding matrices) and for some post-hoc analyses. You can call it with:
ludwig collect_weights [options]
or with:
python -m ludwig.collect weights [options]
from within Ludwig's main directory.
These are the available arguments:
usage: ludwig collect_weights [options]
This script loads a pretrained model and uses it collect weights.
optional arguments:
-h, --help show this help message and exit
-m MODEL_PATH, --model_path MODEL_PATH
model to load
-t TENSORS [TENSORS ...], --tensors TENSORS [TENSORS ...]
tensors to collect
-od OUTPUT_DIRECTORY, --output_directory OUTPUT_DIRECTORY
directory that contains the results
-dbg, --debug enables debugging mode
-l {critical,error,warning,info,debug,notset}, --logging_level {critical,error,warning,info,debug,notset}
the level of logging to use
The three most important arguments are --model_path
where you have to specify the path of the model to load, --tensors
that lets you specify a list of tensor names in the Torch graph that contain the weights you want to collect, and finally --output_directory
that lets you specify where the NPY files (one for each tensor name specified) will be saved.
In order to figure out the names of the tensors containing the weights you want
to collect, use the collect_summary
command.
collect_activations¶
This command lets you load a pre-trained model and input data and collects the values of activations contained in tensors with a specific name in order to save them in a NPY format.
This may be useful in order to visualize the activations (for instance collecting the last layer's activations as embeddings representations of the input datapoint) and for some post-hoc analyses.
You can call it with:
ludwig collect_activations [options]
or with:
python -m ludwig.collect activations [options]
from within Ludwig's main directory.
These are the available arguments:
usage: ludwig collect_activations [options]
This script loads a pretrained model and uses it collect tensors for each
datapoint in the dataset.
optional arguments:
-h, --help show this help message and exit
--dataset DATASET filepath for input dataset
--data_format DATA_FORMAT format of the dataset. Valid values are auto,
csv, excel, feature, fwf, hdf5, html, tables, json,
json, jsonl, parquet, pickle, sas, spss, stata, tsv
-s {training,validation,test,full}, --split {training,validation,test,full}
the split to test the model on
-m MODEL_PATH, --model_path MODEL_PATH
model to load
-lyr LAYER [LAYER ..], --layers LAYER [LAYER ..]
layers to collect
-od OUTPUT_DIRECTORY, --output_directory OUTPUT_DIRECTORY
directory that contains the results
-bs BATCH_SIZE, --batch_size BATCH_SIZE
size of batches
-g GPUS, --gpus GPUS list of gpu to use
-gml GPU_MEMORY, --gpu_memory_limit GPU_MEMORY
maximum memory in MB of gpu memory to allocate per
GPU device
-dpt, --disable_parallel_threads
disable Torch from using multithreading
for reproducibility
-b BACKEND, --backend BACKEND
specifies backend to use for parallel / distributed execution,
defaults to local execution or Horovod if called using horovodrun
-dbg, --debug enables debugging mode
-l {critical,error,warning,info,debug,notset}, --logging_level {critical,error,warning,info,debug,notset}
the level of logging to use
The data related and runtime related arguments (GPUs, batch size, etc.) are the same as the ones used in predict, you can refer to that section for an explanation.
The collect-specific arguments, --model_path
, --tensors
and
--output_directory
, are the same used in collect_weights,
you can refer to that section for an explanation.
export_torchscript¶
Exports a pre-trained model to Torch's torchscript
format.
ludwig export_torchscript [options]
or with:
python -m ludwig.export torchscript [options]
These are the available arguments:
usage: ludwig export_torchscript [options]
This script loads a pretrained model and saves it as torchscript.
optional arguments:
-h, --help show this help message and exit
-m MODEL_PATH, --model_path MODEL_PATH
model to load
-mo, --model_only Script and export the model only.
-d DEVICE, --device DEVICE
Device to use for torchscript tracing (e.g. "cuda" or "cpu"). Ideally, this is the same as the device used
when the model is loaded.
-op OUTPUT_PATH, --output_path OUTPUT_PATH
path where to save the export model. If not specified, defaults to model_path.
-l {critical,error,warning,info,debug,notset}, --logging_level {critical,error,warning,info,debug,notset}
the level of logging to use
For more information, see TorchScript Export
export_neuropod¶
A Ludwig model can be exported as a Neuropod, a mechanism that allows it to be executed in a framework agnostic way.
In order to export a Ludwig model as a Neuropod, first make sure the neuropod
package is installed in your environment together with the appropriate backend (only use Python 3.7+), then run the following command:
ludwig export_neuropod [options]
or with:
python -m ludwig.export neuropod [options]
These are the available arguments:
usage: ludwig export_neuropod [options]
This script loads a pretrained model and uses it collect weights.
optional arguments:
-h, --help show this help message and exit
-m MODEL_PATH, --model_path MODEL_PATH
model to load
-mn MODEL_NAME, --model_name MODEL_NAME
model name
-od OUTPUT_PATH, --output_path OUTPUT_PATH
path where to save the export model
-l {critical,error,warning,info,debug,notset}, --logging_level {critical,error,warning,info,debug,notset}
the level of logging to use
This functionality has been tested with neuropod==0.2.0
.
export_mlflow¶
A Ludwig model can be exported as an mlflow.pyfunc model, which allows it to be executed in a framework agnostic way.
There are two ways to export a Ludwig model to MLflow:
- Convert a saved model directory on disk to the MLflow format on disk.
- Register a saved model directory on disk or in an existing MLflow experiment to an MLflow model registry.
For the first approach, you only need to provide the location of the saved Ludwig model locally and the location where the model should be written to on local disk:
ludwig export_mlflow --model_path /saved/ludwig/model --output_path /exported/mlflow/model
For the second, you will need to provide a registered model name used by the model registry:
ludwig export_mlflow --model_path /saved/ludwig/model --output_path relative/model/path --registered_model_name my_ludwig_model
preprocess¶
Preprocess data and saves it into HDF5 and JSON format. The preprocessed files can be then used for performing training, prediction and evaluation. The advantage is that, being the data already preprocessed, if multiple models have to be trained on the same data, the preprocessed files act as a cache to avoid performing preprocessing multiple times.
ludwig preprocess [options]
or with:
python -m ludwig.preprocess [options]
These are the available arguments:
usage: ludwig preprocess [options]
This script preprocess a dataset
optional arguments:
-h, --help show this help message and exit
--dataset DATASET input data file path. If it has a split column, it
will be used for splitting (0: train, 1: validation,
2: test), otherwise the dataset will be randomly split
--training_set TRAINING_SET
input train data file path
--validation_set VALIDATION_SET
input validation data file path
--test_set TEST_SET input test data file path
--training_set_metadata TRAINING_SET_METADATA
input metadata JSON file path. An intermediate
preprocessed containing the mappings of the input
file created the first time a file is used, in the
same directory with the same name and a .json
extension
--data_format {auto,csv,excel,feather,fwf,hdf5,htmltables,json,jsonl,parquet,pickle,sas,spss,stata,tsv}
format of the input data
-pc PREPROCESSING_CONFIG, --preprocessing_config PREPROCESSING_CONFIG
preprocessing config. Uses the same format of config,
but ignores encoder specific parameters, decoder
specific parameters, combiner and training parameters
-pcf PREPROCESSING_CONFIG_FILE, --preprocessing_config_file PREPROCESSING_CONFIG_FILE
YAML file describing the preprocessing. Ignores
--preprocessing_config.Uses the same format of config,
but ignores encoder specific parameters, decoder
specific parameters, combiner and training parameters
-rs RANDOM_SEED, --random_seed RANDOM_SEED
a random seed that is going to be used anywhere there
is a call to a random number generator: data
splitting, parameter initialization and training set
shuffling
-dbg, --debug enables debugging mode
-l {critical,error,warning,info,debug,notset}, --logging_level {critical,error,warning,info,debug,notset}
the level of logging to use
synthesize_dataset¶
Creates synthetic data for testing purposes depending on the feature list parameters provided in YAML format.
ludwig synthesize_dataset [options]
or with:
python -m ludwig.data.dataset_synthesizer [options]
These are the available arguments:
usage: ludwig synthesize_dataset [options]
This script generates a synthetic dataset.
optional arguments:
-h, --help show this help message and exit
-od OUTPUT_PATH, --output_path OUTPUT_PATH
output CSV file path
-d DATASET_SIZE, --dataset_size DATASET_SIZE
size of the dataset
-f FEATURES, --features FEATURES
list of features to generate in YAML format. Provide a
list containing one dictionary for each feature, each
dictionary must include a name, a type and can include
some generation parameters depending on the type
Process finished with exit code 0
Example:
ludwig synthesize_dataset --features="[ \
{name: text, type: text}, \
{name: category, type: category}, \
{name: number, type: number}, \
{name: binary, type: binary}, \
{name: set, type: set}, \
{name: bag, type: bag}, \
{name: sequence, type: sequence}, \
{name: timeseries, type: timeseries}, \
{name: date, type: date}, \
{name: h3, type: h3}, \
{name: vector, type: vector}, \
{name: image, type: image} \
]" --dataset_size=10 --output_path=synthetic_dataset.csv
The available parameters depend on the feature type.
binary
prob
(float, default:0.5
): probability of generatingtrue
.cycle
(boolean, default:false
): cycle through values instead of sampling.
number
min
(float, default:0
): minimum value of the range of values to generate.max
(float, default:1
): maximum value of the range of values to generate.
category
vocab_size
(int, default:10
): size of the vocabulary to sample from.cycle
(boolean, default:false
): cycle through values instead of sampling.
sequence
vocab_size
(int, default:10
): size of the vocabulary to sample from.max_len
(int, default:10
): maximum length of the generated sequence.min_len
(int, default:null
): ifnull
all sequences will be of sizemax_len
. If a value is provided, the length will be randomly determined betweenmin_len
andmax_len
.
set
vocab_size
(int, default:10
): size of the vocabulary to sample from.max_len
(int, default:10
): maximum length of the generated set.
bag
vocab_size
(int, default:10
): size of the vocabulary to sample from.max_len
(int, default:10
): maximum length of the generated set.
text
vocab_size
(int, default:10
): size of the vocabulary to sample from.max_len
(int, default:10
): maximum length of the generated sequence, lengths will be randomly sampled betweenmax_len - 20%
andmax_len
.
timeseries
max_len
(int, default:10
): maximum length of the generated sequence.min
(float, default:0
): minimum value of the range of values to generate.max
(float, default:1
): maximum value of the range of values to generate.
audio
destination_folder
(str): folder where the generated audio files will be saved.preprocessing: {audio_file_length_limit_in_s}
(int, default:1
): length of the generated audio in seconds.
image
destination_folder
(str): folder where the generated image files will be saved.preprocessing: {height}
(int, default:28
): height of the generated image in pixels.preprocessing: {width}
(int, default:28
): width of the generated image in pixels.preprocessing: {num_channels}
(int, default:1
): number of channels of the generated images. Valid values are1
,3
,4
.preprocessing: {infer_image_dimensions}
(boolean, default:true
): whether to transform differently-sized images to the same width/height dimensions. Target dimensions are inferred by taking the average dimensions of the firstinfer_image_sample_size
images, then applyinginfer_image_max_height
andinfer_image_max_width
. This parameter has no effect if explicitwidth
andheight
are specified.preprocessing: {infer_image_sample_size}
(int, default100
): sample size ofinfer_image_dimensions
.preprocessing: {infer_image_max_height}
(int, default256
): maximum height of an image transformed usinginfer_image_dimensions
.preprocessing: {infer_image_max_width}
(int, default256
): maximum width of an image transformed usinginfer_image_dimensions
.
date
No parameters.
h3
No parameters.
vector
vector_size
(int, default:10
): size of the vectors to generate.