HugeCTR Python Interface

About the HugeCTR Python Interface

As a recommendation system domain specific framework, HugeCTR has a set of high level abstracted Python Interface which includes training API and inference API. Users only need to focus on algorithm design, the training and inference jobs can be automatically deployed on the specific hardware topology in the optimized manner. From version 3.1, users can complete the process of training and inference without manually writing JSON configuration files. All supported functionalities have been wrapped into high-level Python APIs. Meanwhile, the low-level training API is maintained for users who want to have precise control of each training iteration and each evaluation step. Still, the high-level training API is friendly to users who are already familiar with other deep learning frameworks like Keras and it is worthwhile to switch to it from low-level training API. Please refer to HugeCTR Python Interface Notebook to get familiar with the workflow of HugeCTR training and inference. Meanwhile we have a lot of samples for demonstration in the samples directory of the HugeCTR repository.

High-level Training API

For HugeCTR high-level training API, the core data structures are Solver, EmbeddingTrainingCacheParams, DataReaderParams, OptParamsPy, Input, SparseEmbedding, DenseLayer and Model. You can create a Model instance with Solver, EmbeddingTrainingCacheParams, DataReaderParams and OptParamsPy instances, and then add instances of Input, SparseEmbedding or DenseLayer to it. After compiling the model with the Model.compile() method, you can start the epoch mode or non-epoch mode training by simply calling the Model.fit() method. Moreover, the Model.summary() method gives you an overview of the model structure. We also provide some other methods, such as saving the model graph to a JSON file, constructing the model graph based on the saved JSON file, loading model weights and optimizer status, etc.

Solver

CreateSolver method

hugectr.CreateSolver()

CreateSolver returns an Solver object according to the custom argument values,which specify the training resources.

Arguments

  • model_name: String, the name of the model. The default value is empty string. If you want to dump the model graph and save the model weights for inference, a unique value should be specified for each model that needs to be deployed.

  • seed: A random seed to be specified. The default value is 0.

  • lr_policy: The learning rate policy which suppots only fixed. The default value is LrPolicy_t.fixed.

  • lr: The learning rate, which is also the base learning rate for the learning rate scheduler. The default value is 0.001.

  • warmup_steps: The warmup steps for the internal learning rate scheduler within Model instance. The default value is 1.

  • decay_start: The step at which the learning rate decay starts for the internal learning rate scheduler within Model instance. The default value is 0.

  • decay_steps: The number of steps of the learning rate decay for the internal learning rate scheduler within Model instance. The default value is 1.

  • decay_power: The power of the learning rate decay for the internal learning rate scheduler within Model instance. The default value is 2.

  • end_lr: The final learning rate for the internal learning rate scheduler within Model instance. The default value is 0. Please refer to SGD Optimizer and Learning Rate Scheduling if you want to get detailed information about LearningRateScheduler.

  • max_eval_batches: Maximum number of batches used in evaluation. It is recommended that the number is equal to or bigger than the actual number of bathces in the evaluation dataset. The default value is 100.

  • batchsize_eval: Minibatch size used in evaluation. The default value is 2048. Note that batchsize here is the global batch size across gpus and nodes, not per worker batch size.

  • batchsize: Minibatch size used in training. The default value is 2048. Note that batchsize here is the global batch size across gpus and nodes , not per worker batch size.

  • vvgpu: GPU indices used in the training process, which has two levels. For example: [[0,1],[1,2]] indicates that two physical nodes (each physical node can have multiple NUMA nodes) are used. In the first node, GPUs 0 and 1 are used while GPUs 1 and 2 are used for the second node. It is also possible to specify non-continuous GPU indices such as [0, 2, 4, 7]. The default value is [[0]].

  • repeat_dataset: Whether to repeat the dataset for training. If the value is True, non-epoch mode training will be employed. Otherwise, epoch mode training will be adopted. The default value is True.

  • use_mixed_precision: Whether to enable mixed precision training. The default value is False.

  • enable_tf32_compute: If you want to accelerate FP32 matrix multiplications within the FullyConnectedLayer and InteractionLayer, set this value to True. The default value is False.

  • scaler: The scaler to be used when mixed precision training is enabled. Only 128, 256, 512, and 1024 scalers are supported for mixed precision training. The default value is 1.0, which corresponds to no mixed precision training.

  • metrics_spec: Map of enabled evaluation metrics. You can use either AUC, AverageLoss, HitRate, or any combination of them. For AUC, you can set its threshold, such as {MetricsType.AUC: 0.8025}, so that the training terminates when it reaches that threshold. The default value is {MetricsType.AUC: 1.0}. Multiple metrics can be specified in one job. For example: metrics_spec = {hugectr.MetricsType.HitRate: 0.8, hugectr.MetricsType.AverageLoss:0.0, hugectr.MetricsType.AUC: 1.0})

  • i64_input_key: If your dataset format is Norm, you can choose the data type of each input key. For the Parquet format dataset generated by NVTabular, only I64 is allowed. For the Raw dataset format, only I32 is allowed. Set this value to True when you need to use I64 input key. The default value is False.

  • use_algorithm_search: Whether to use algorithm search for cublasGemmEx within the FullyConnectedLayer. The default value is True.

  • use_cuda_graph: Whether to enable cuda graph in the training. If you are using AsyncDataReader and HybridEmbedding, all GPU tasks including embeddings and network inside each training iteration will be packed into a single CUDA Graph. Otherwise only the CUDA Graph includes the network only. The default value is True.

  • device_layout: this option is deprecated and no longer used.

  • train_intra_iteration_overlap: Whether to enable overlap inside every training iteration. If true, hugectr detects the model toplogy and tries to overlap among DataReader, Embedding and Network in every training iteration. The default value is False.

  • train_inter_iteration_overlap: Whether to enable overlap between training iterations. If true, hugectr tries to fetch some data copy/computation in the next iteration during the current iteration, so that the next iteraction can start earlier. The default value is False.

  • eval_intra_iteration_overlap: Whether to enable overlap inside every eval iteration. The knob provides similar functionality with train_intra_iteration_overlap while it applies to evaluation iterations. The default value is False.

  • eval_inter_iteration_overlap: Whether to enable overlap between eval iteration. The knob provides similar functionality with train_inter_iteration_overlap while it applies to evaluation iterations. The default value is False.

  • all_reduce_algo: The algorithm to be used for all reduce. The supported options are AllReduceAlgo.OneShot and AllReduceAlgo.NCCL. The default value is AllReduceAlgo.NCCL. When you are doing multi-node training, AllReduceAlgo.OneShot will require RDMA support while AllReduceAlgo.NCCL can run on both RDMA and non-RDMA hardware.

  • grouped_all_reduce: The default value is False. If True, the gradients for the dense network and the gradients for data-parallel embedding are grouped and all reduced in one kernel, effectively combining two small all-reduce operations into a single larger one for higher efficiency. Requirements: Hybrid embedding is used (see HybridEmbeddingParam).

  • num_iterations_statistics: The number of batches used to perform statistics for hybrid embedding. The default value is 20. Requirement: The data reader is asynchronous (see AsyncParam).

Example:

solver = hugectr.CreateSolver(max_eval_batches = 300,
                              batchsize_eval = 16384,
                              batchsize = 16384,
                              lr = 0.001,
                              vvgpu = [[0]],
                              repeat_dataset = True,
                              i64_input_key = True)

CreateETC method

hugectr.CreateETC()

CreateETC should only be called when using the Embedding Training Cache (ETC) feature. It returns a EmbeddingTrainingCacheParams object that specifies the parameters for initializing a EmbeddingTrainingCache instance.

Arguments

  • ps_types: A list specifies types of parameter servers (PS) of each embedding table. Available PS choices for embeddings are:

    • hugectr.TrainPSType_t.Staged

      • The whole embedding table will be loaded into the host memory in the initialization stage.

      • It requires the size of host memory should be large enough to hold the embedding table along with the optimizer states (if any).

      • Staged type offers better loading and dumping bandwidth than the Cached PS.

    • hugectr.TrainPSType_t.Cached

      • A sub-portion of the embedding table will be dynamically cached in the host memory, and it adopts a runtime eviction/insertion mechanism to update the cached table.

      • The size of the cached table is configurable, which can be substantially smaller than the size of the embedding table stored in the SSD or various kinds of filesystems. E.g., embedding table size (1 TB) v.s. cache size (100 GB).

      • The bandwidth of Cached PS is mainly affected by the hit rate. If the hit rate is 100 %, its bandwidth tends to the Staged PS; Otherwise, if the hit rate is 0 %, the bandwidth equals the random-accessing bandwidth of SSD.

  • sparse_models: A path list of embedding table(s). If the provided path points to an existing table, this table will be used for incremental training. Otherwise, the newly generated table will be written into this path after training.

  • local_paths: A path list for storing the temporary embedding table. Its length should be equal to the number of MPI ranks. Each entry in this list should be a path pointing to the local SSD of this node.

    This entry is only required when there is hugectr.TrainPSType_t.Cached in ps_types.

  • hcache_configs: A path list of the configurations of Cached PS. Please check Cached-PS Configuration for more descriptions.

    • If only one configuration is provided, it will be used for all Cached PS.

    • Otherwise, you need to provide one configuration for each Cached PS. And the ith configuration in hcache_configs will be used for the ith occurrence of Cached PS in ps_types.

    This entry is only required when there is hugectr.TrainPSType_t.Cached in ps_types.

Note that the Staged and Cached PS can be used together for a model with more than one embedding tables.

Example usage of the CreateETC() API can be found in Configuration.

For the usage of the ETC feature in real cases, please check the HugeCTR Continuous Training notebook.

AsyncParam

AsyncParam class

hugectr.AsyncParam()

A data reader can be optimized using asynchronous reading. This is done by creating the data reader with a async_param argument (see DataReaderParams), which is of type AsyncParam. AsyncParam specifies the parameters related to asynchronous raw data reader, An asynchronous data reader uses the Linux asynchronous I/O library (AIO) to achieve peak I/O throughput. Requirements: The input dataset has only one-hot feature items and is in raw format.

Arguments

  • num_threads: Integer, the number of the data reading threads, should be at least 1 per GPU。 There is NO default value.

  • num_batches_per_thread: Integer, the number of the batches each data reader thread works on simultaneously, typically 2-4. There is NO default value.

  • max_num_requests_per_thread: Integer, the max number of individual IO requests for each thread. It should be a multiple of num_batches_per_thread and no less than 2 * num_batches_per_thread. The value 72 should work in most cases. There is NO default value.

  • io_depth: Integer, the size of the asynchronous IO queue, the value 4 should work in most cases. There is NO default value.

  • io_alignment: Integer, the byte alignment of IO requests, the value 512 or 4096 should work in most cases. There is NO default value.

  • shuffle: Boolean, if this option is enabled, the order in which the batches are fed into training will be randomized. There is NO default value.

  • aligned_type: The supported types include hugectr.Alignment_t.Auto and hugectr.Alignment_t.Non. If hugectr.Alignment_t.Auto is chosen, the dimension of dense input will be padded to an 8-aligned value. There is NO default value.

Example:

async_param = hugectr.AsyncParam(32, 4, 10, 2, 512, True, hugectr.Alignment_t.Non)

HybridEmbeddingParam

HybridEmbeddingParam class

hugectr.HybridEmbeddingParam()

A sparse embedding layer can be optimized using hybrid embedding. Hybrid embedding is designed to overcome the bandwidth constraint that is imposed by the embedding part of the embedding training workload by algorithmically reducing the traffic over the network. Hybrid embedding can improve performance in multi-node and multi-GPU deployments with one-hot data. Conversely, hybrid embedding does not improve performance on a single-machine and single-GPU deployment or with multi-hot encoded data.

You can use hybrid embedding by creating a sparse embedding layer with a hybrid_embedding_param argument that is of type HybridEmbeddingParam and specifying the parameters that are related to hybrid embedding.

Requirements: The input dataset has only one-hot feature items and the model uses the SGD optimizer.

For information about creating a sparse embedding layer, refer to the class documentation.

Arguments

  • max_num_frequent_categories: Integer, the maximum number of frequent categories in unit of batch size. This argument does not have a default value.

  • max_num_infrequent_samples: Integer, the maximum number of infrequent samples in unit of batch size. This argument does not have a default value.

  • p_dup_max: Float, the maximum probability that the category appears more than once within the gpu-batch. This way of determining the number of frequent categories is used in single-node or NVLink connected systems only. This argument does not have a default value.

  • max_all_reduce_bandwidth: Float, the algorithmic bandwidth of the all reduce. This argument does not have a default value.

  • max_all_to_all_bandwidth: Float, the algorithmic bandwidth of the all-to-all. The unit of bandwidth is per-GPU. This argument does not have a default value.

  • efficiency_bandwidth_ratio: Float, this argument is used in combination with max_all_reduce_bandwidth and max_all_to_all_bandwidth to determine the optimal threshold for the number of frequent categories. This way of determining the frequent categories is used for multi node only. This argument does not have a default value.

  • communication_type: The type of communication that is being used. The supported types include CommunicationType.IB_NVLink, CommunicationType.IB_NVLink_Hier and CommunicationType.NVLink_SingleNode. This argument does not have a default value.

  • hybrid_embedding_type: The type of hybrid embedding, which supports only HybridEmbeddingType.Distributed for now. This argument does not have a default value.

Example:

hybrid_embedding_param = hugectr.HybridEmbeddingParam(2, -1, 0.01, 1.3e11, 1.9e11, 1.0,
                                                    hugectr.CommunicationType.IB_NVLink_Hier,
                                                    hugectr.HybridEmbeddingType.Distributed))

DataReaderParams

DataReaderParams class

hugectr.DataReaderParams()

DataReaderParams specifies the parameters related to the data reader. HugeCTR currently supports three dataset formats, i.e., Norm, Raw and Parquet. An DataReaderParams instance is required to initialize the Model instance.

Arguments

  • data_reader_type: The type of the data reader which should be consistent with the dataset format. Specify one of the following types:

    • hugectr.DataReaderType_t.Norm

    • hugectr.DataReaderType_t.Raw

    • hugectr.DataReaderType_t.Parquet

    • DataReaderType_t.RawAsync

  • source: List[str] or String, the training dataset source. For Norm or Parquet dataset, specify the file list of training data, such as source = "file_list.txt". For Raw dataset, specify a single training file, such as source = "train_data.bin". When using the embedding training cache, you can specify several file lists, such as source = ["file_list.1.txt", "file_list.2.txt"]. This argument has no default value and you must specify a value.

  • keyset: List[str] or String, the keyset files. This argument is only valid when you use the embedding training cache. The value should correspond to the value for the source argument. For example, you can specify source = ["file_list.1.txt", "file_list.2.txt"] and keyset = ["file_list.1.keyset", "file_list.2.keyset"] The example shows the one-to-one correspondence between the source and keyset values.

  • eval_source: String, the evaluation dataset source. For Norm or Parquet dataset, specify the file list of the evaluation data. For Raw dataset, specify a single evaluation file. This argument has no default value and you must specify a value.

  • check_type: The data error detection mechanism. Specify hugectr.Check_t.Sum (CheckSum) or hugectr.Check_t.Non (no detection). This argument has no default value and you must specify a value.

  • cache_eval_data: Integer, the cache size of evaluation data on device. Specify a value that is greater than zero to restrict the memory use. The default value is 0.

  • num_samples: Integer, the number of samples in the training dataset. This argument is valid for the Raw dataset format only. The default value is 0.

  • eval_num_samples: Integer, the number of samples in the evaluation dataset. This argument is valid for the Raw dataset format only. The default value is 0.

  • float_label_dense: Boolean, this argument is valid for the Raw dataset format only. When set to True, the label and dense features for each sample are interpreted as float values. Otherwise, they are read as integer values while the dense features are preprocessed with \(log(dense[i] + \text{1.f})\). The default value is True.

  • num_workers: Integer, the number of data reader workers to load data concurrently. You can empirically decide the best value based on your dataset and training environment. The default value is 12.

  • slot_size_array: List[int], specify the maximum key value for each slot. Refer to the following equation. The array should be consistent with that of the sparse input. HugeCTR requires this argument for Parquet format data and RawAsync format when you want to add an offset to the input key. The default value is an empty list.

    The following equation shows how to determine the values to specify:

    \(slot\_size\_array[k] = \max\limits_i slot^k_i + 1\)

  • data_source_params: DataSourceParams(), specify the configurations of the data sources(Local, HDFS, or others) for data reading.

  • async_param: AsyncParam, the parameters for async raw data reader. Please find more information in the AsyncParam section in this document.

Dataset formats

We support the following dataset formats within our DataReaderParams.

../_images/dataset_format.png
Fig. 1: (a) Norm (b) Raw (c) Parquet Dataset Formats



Norm

To maximize the data loading performance and minimize the storage, the Norm dataset format consists of a collection of binary data files and an ASCII formatted file list. The model file should specify the file name of the training and testing (evaluation) set, maximum elements (key) in a sample, and the label dimensions as shown in Fig. 1 (a).

Data Files

A data file is the minimum reading granularity for a reading thread, so at least 10 files in each file list are required to achieve the best performance. A data file consists of a header and actual tabular data.

Header Definition:

typedef struct DataSetHeader_ {
  long long error_check;        // 0: no error check; 1: check_num
  long long number_of_records;  // the number of samples in this data file
  long long label_dim;          // dimension of label
  long long dense_dim;          // dimension of dense feature
  long long slot_num;           // slot_num for each embedding
  long long reserved[3];        // reserved for future use
} DataSetHeader;

Data Definition (each sample):

typedef struct Data_ {
  int length;                   // bytes in this sample (optional: only in check_sum mode )
  float label[label_dim];
  float dense[dense_dim];
  Slot slots[slot_num];
  char checkbits;                // checkbit for this sample (optional: only in checksum mode)
} Data;

typedef struct Slot_ {
  int nnz;
  unsigned int*  keys; // changeable to `long long` with `"input_key_type"` in `solver` object of the configuration file.
} Slot;

The Data field often has a lot of samples. Each sample starts with the labels formatted as integers and followed by nnz (number of nonzero) with the input key using the long long (or unsigned int) format as shown in Fig. 1 (a).

The input keys for categorical are distributed to the slots with no overlap allowed. For example: slot[0] = {0,10,32,45}, slot[1] = {1,2,5,67}. If there is any overlap, it will cause an undefined behavior. For example, given slot[0] = {0,10,32,45}, slot[1] = {1,10,5,67}, the table looking up the 10 key will produce different results based on how the slots are assigned to the GPUs.

File List

The first line of a file list should be the number of data files in the dataset with the paths to those files listed below as shown here:

$ cat simple_sparse_embedding_file_list.txt
10
./simple_sparse_embedding/simple_sparse_embedding0.data
./simple_sparse_embedding/simple_sparse_embedding1.data
./simple_sparse_embedding/simple_sparse_embedding2.data
./simple_sparse_embedding/simple_sparse_embedding3.data
./simple_sparse_embedding/simple_sparse_embedding4.data
./simple_sparse_embedding/simple_sparse_embedding5.data
./simple_sparse_embedding/simple_sparse_embedding6.data
./simple_sparse_embedding/simple_sparse_embedding7.data
./simple_sparse_embedding/simple_sparse_embedding8.data
./simple_sparse_embedding/simple_sparse_embedding9.data

Example:

reader = hugectr.DataReaderParams(data_reader_type = hugectr.DataReaderType_t.Norm,
                                  source = ["./wdl_norm/file_list.txt"],
                                  eval_source = "./wdl_norm/file_list_test.txt",
                                  check_type = hugectr.Check_t.Sum)

Raw

The Raw dataset format is different from the Norm dataset format in that the training data appears in one binary file using int32. Fig. 1 (b) shows the structure of a Raw dataset sample.

NOTE: Only one-hot data is accepted with this format.

The Raw dataset format can be used with embedding type LocalizedSlotSparseEmbeddingOneHot only.

Example:

reader = hugectr.DataReaderParams(data_reader_type = hugectr.DataReaderType_t.Raw,
                                  source = ["./wdl_raw/train_data.bin"],
                                  eval_source = "./wdl_raw/validation_data.bin",
                                  check_type = hugectr.Check_t.Sum)

Parquet

Parquet is a column-oriented, open source, and free data format. It is available to any project in the Apache Hadoop ecosystem. To reduce the file size, it supports compression and encoding. Fig. 1 © shows an example Parquet dataset. For additional information, see the parquet documentation.

Please note the following:

  • Nested column types are not currently supported in the Parquet data loader.

  • Any missing values in a column are not allowed.

  • Like the Norm dataset format, the label and dense feature columns should use the float format.

  • The Slot feature columns should use the Int64 format.

  • The data columns within the Parquet file can be arranged in any order.

  • To obtain the required information from all the rows in each parquet file and column index mapping for each label, dense (numerical), and slot (categorical) feature, a separate _metadata.json file is required.

Example _metadata.json file:

{
   "file_stats":[
      {
         "file_name":"file0.parquet",
         "num_rows":409600
      },
      {
         "file_name":"file1.parquet",
         "num_rows":409600
      }
   ],
   "cats":[
      {
         "col_name":"C1",
         "index":4
      },
      {
         "col_name":"C2",
         "index":5
      },
      {
         "col_name":"C3",
         "index":6
      },
      {
         "col_name":"C4",
         "index":7
      }
   ],
   "conts":[
      {
         "col_name":"I1",
         "index":1
      },
      {
         "col_name":"I2",
         "index":2
      },
      {
         "col_name":"I3",
         "index":3
      }
   ],
   "labels":[
      {
         "col_name":"label",
         "index":0
      }
   ]
}
reader = hugectr.DataReaderParams(data_reader_type = hugectr.DataReaderType_t.Parquet,
                                  source = ["./parquet_data/train/_file_list.txt"],
                                  eval_source = "./parquet_data/val/_file_list.txt",
                                  check_type = hugectr.Check_t.Non,
                                  slot_size_array = [10000, 50000, 20000, 300])

We provide an option to add offset for each slot by specifying slot_size_array. slot_size_array is an array whose length is equal to the number of slots. To avoid duplicate keys after adding offset, we need to ensure that the key range of the i-th slot is between 0 and slot_size_array[i]. We will do the offset in this way: for i-th slot key, we add it with offset slot_size_array[0] + slot_size_array[1] + … + slot_size_array[i - 1]. In the configuration snippet noted above, for the 0th slot, offset 0 will be added. For the 1st slot, offset 10000 will be added. And for the third slot, offset 60000 will be added. The length of slot_size_array should be equal to the length of "cats" entry in _metadata.json.

The _metadata.json is generated by NVTabular preprocessing and reside in the same folder of the file list. Basically, it contain four entries of "file_stats" (file statistics), "cats" (categorical columns), "conts" (continuous columns), and "labels" (label columns). The "col_name" and "index" in _metadata.json indicate the name and the index of a specific column in the parquet data frame. You can also edit the generated _metadata.json to only read the desired columns for model training. For example, you can modify the above _metadata.json and change the configuration correspondingly:

Example _metadata.json file after edits:

{
   "file_stats":[
      {
         "file_name":"file0.parquet",
         "num_rows":409600
      },
      {
         "file_name":"file1.parquet",
         "num_rows":409600
      }
   ],
   "cats":[
      {
         "col_name":"C2",
         "index":5
      },
      {
         "col_name":"C4",
         "index":7
      }
   ],
   "conts":[
      {
         "col_name":"I1",
         "index":1
      },
      {
         "col_name":"I3",
         "index":3
      }
   ],
   "labels":[
      {
         "col_name":"label",
         "index":0
      }
   ]
}
reader = hugectr.DataReaderParams(data_reader_type = hugectr.DataReaderType_t.Parquet,
                                  source = ["./parquet_data/train/_file_list.txt"],
                                  eval_source = "./parquet_data/val/_file_list.txt",
                                  check_type = hugectr.Check_t.Non,
                                  slot_size_array = [50000, 300])

OptParamsPy

CreateOptimizer method

hugectr.CreateOptimizer()

CreateOptimizer returns an OptParamsPy object according to the custom argument values,which specify the optimizer type and the corresponding hyperparameters. The OptParamsPy object will be used to initialize the Model instance and it applies to the weights of dense layers. Sparse embedding layers which do not have a specified optimizer will adopt this optimizer as well. Please NOTE that the hyperparameters should be configured meticulously when mixed precision training is employed, e.g., the epsilon value for the Adam optimizer should be set larger.

The embedding update supports three algorithms specified with update_type:

  • Local (default value): The optimizer will only update the hot columns (embedding vectors which is hit in this iteration of training) of an embedding in each iteration.

  • Global: The optimizer will update all the columns. The embedding update type takes longer than the other embedding update types.

  • LazyGlobal: The optimizer will only update the hot columns of an embedding in each iteration while using different semantics from the local and global updates.

Arguments

  • optimizer_type: The optimizer type to be used. The supported types include hugectr.Optimizer_t.Adam, hugectr.Optimizer_t.MomentumSGD, hugectr.Optimizer_t.Nesterov and hugectr.Optimizer_t.SGD, hugectr.Optimizer_t.Adagrad. The default value is hugectr.Optimizer_t.Adam.

  • update_type: The update type for the embedding. The supported types include hugectr.Update_t.Global, hugectr.Update_t.Local, and hugectr.Update_t.LazyGlobal(Adam only). The default value is hugectr.Update_t.Global.

  • beta1: The beta1 value when using Adam optimizer. The default value is 0.9.

  • beta2: The beta2 value when using Adam optimizer. The default value is 0.999.

  • epsilon: The epsilon value when using Adam optimizer. This argument should be well configured when mixed precision training is employed. The default value is 1e-7.

  • momentum_factor: The momentum_factor value when using MomentumSGD or Nesterov optimizer. The default value is 0.

  • atomic_update: Whether to employ atomic update when using SGD optimizer. The default value is True.

Example:

optimizer = hugectr.CreateOptimizer(optimizer_type = hugectr.Optimizer_t.Adam,
                                    update_type = hugectr.Update_t.Global,
                                    beta1 = 0.9,
                                    beta2 = 0.999,
                                    epsilon = 0.0000001)

Layers

There are three major kinds of layer in HugeCTR:

Please refer to hugectr_layer_book for detail guides on how to use different layer types.

Model

Model class

hugectr.Model()

Model groups data input, embeddings and dense network into an object with traning features. The construction of Model requires a Solver instance , a DataReaderParams instance, an OptParamsPy instance and a EmbeddingTrainingCacheParams instance (optional).

Arguments

  • solver: A hugectr.Solver object, the solver configuration for the model.

  • reader_params: A hugectr.DataReaderParams object, the data reader configuration for the model.

  • opt_params: A hugectr.OptParamsPy object, the optimizer configuration for the model.

  • etc: A hugectr.EmbeddingTrainingCacheParams object, the embedding training cache configuration for the model. This argument should only be provided when using the embedding training cache feature.


add method

hugectr.Model.add()

The add method of Model adds an instance of Input, SparseEmbedding, DenseLayer, GroupDenseLayer, or EmbeddingCollection to the created Model object. Typically, a Model object is comprised of one Input, several SparseEmbedding and a series of DenseLayer instances. Please note that the loss function for HugeCTR model training is taken as a DenseLayer instance.

Arguments

  • input or sparse_embedding or dense_layer: This method is an overloaded method that can accept hugectr.Input, hugectr.SparseEmbedding, hugectr.DenseLayer, hugectr.GroupDenseLayer, or hugectr.EmbeddingCollection as an argument. It allows the users to construct their model flexibly without the JSON configuration file.

Refer to the HugeCTR Layer Classes and Methods for information about the layers and embedding collection.


compile method

hugectr.Model.compile()

This method requires no extra arguments. It allocates the internal buffer and initializes the model. For multi-task models, can optionally take two arguments.

Arguments

  • loss_names: List of Strings, the list of loss label names to provide weights for.

  • loss_weights: List of Floats, the weights to be assigned to each loss label. Number of elements must match the number of loss_names.


fit method

hugectr.Model.fit()

It trains the model for a fixed number of epochs (epoch mode) or iterations (non-epoch mode). You can switch the mode of training through different configurations. To use epoch mode training, repeat_dataset within CreateSolver() should be set as False and num_epochs within Model.fit() should be set as a positive number. To use non-epoch mode training, repeat_dataset within CreateSolver() should be set as True and max_iter within Model.fit() should be set as a positive number.

Arguments

  • num_epochs: Integer, the number of epochs for epoch mode training. It will be ignored if repeat_dataset is True. The default value is 0.

  • max_iter: Integer, the maximum iteration of non-epoch mode training. It will be ignored if repeat_dataset is False. The default value is 2000.

  • display: Integer, the interval of iterations at which the training loss will be displayed. The default value is 200.

  • eval_interval: Integer, the interval of iterations at which the evaluation will be executed. The default value is 1000.

  • snapshot: Integer, the interval of iterations at which the snapshot model weights and optimizer states will be saved to files. This argument is invalid when embedding training cache is being used, which means no model parameters will be saved. The default value is 10000.

  • snapshot_prefix: String, the prefix of the file names for the saved model weights and optimizer states. This argument is invalid when embedding training cache is being used, which means no model parameters will be saved. The default value is ''. Remote file systems(HDFS and S3) are also supported. For example, for HDFS, the prefix can be hdfs://localhost:9000/dir/to/model. For S3, the prefix should be either virtual-hosted-style or path-style and contains the region information. For examples, take a look at the AWS official documentation. Please note that dumping models to remote file system when enabled MPI is not supported yet.


summary method

hugectr.Model.summary()

This method takes no extra arguments and prints a string summary of the model. Users can have an overview of the model structure with this method. Please NOTE that the first dimension of displayed tensors is the per-GPU batchsize.


graph_to_json method

hugectr.Model.graph_to_json()

This method saves the model graph to a JSON file, which can be used for continuous training and inference.

Arguments

  • graph_config_file: The JSON file to which the model graph will be saved. There is NO default value and it should be specified by users.


construct_from_json method

hugectr.Model.construct_from_json()

This method constructs the model graph from a saved JSON file, which is useful for continuous training and fine-tune.

Arguments

  • graph_config_file: The saved JSON file from which the model graph will be constructed. There is NO default value and it should be specified by users.

  • include_dense_network: Boolean, whether to include the dense network when constructing the model graph. If it is True, the whole model graph will be constructed, then both saved sparse model weights and dense model weights can be loaded. If it is False, only the sparse embedding layers will be constructed and the corresponding sparse model weights can be loaded, which enables users to construct a new dense network on top of that. Please NOTE that the HugeCTR layers are organized by names and you can check the input name, output name and output shape and of the added layers with Model.summary(). There is NO default value and it should be specified by users.


load_dense_weights method

hugectr.Model.load_dense_weights()

This method load the dense weights from the saved dense model file.

Arguments

  • dense_model_file: String, the saved dense model file from which the dense weights will be loaded. There is NO default value and it should be specified by users. Remote file systems(HDFS and S3) are also supported. For example, for HDFS, the path can be hdfs://localhost:9000/dir/to/model. For S3, the path should be either virtual-hosted-style or path-style and contains the region information. For examples, take a look at the AWS official documentation.


load_dense_optimizer_states method

hugectr.Model.load_dense_optimizer_states()

This method load the dense optimizer states from the saved dense optimizer states file.

Arguments

  • dense_opt_states_file: String, the saved dense optimizer states file from which the dense optimizer states will be loaded. There is NO default value and it should be specified by users. Remote file systems(HDFS and S3) are also supported. For example, for HDFS, the path can be hdfs://localhost:9000/dir/to/model. For S3, the prefix should be either virtual-hosted-style or path-style and contains the region information. For examples, take a look at the AWS official documentation.


load_sparse_weights method

hugectr.Model.load_sparse_weights()

This method load the sparse weights from the saved sparse embedding files.

Implementation Ⅰ

Arguments

  • sparse_embedding_files: List[str], the sparse embedding files from which the sparse weights will be loaded. The number of files should equal to that of the sparse embedding layers in the model. There is NO default value and it should be specified by users. Remote file systems(HDFS and S3) are also supported. For example, for HDFS, the path can be hdfs://localhost:9000/dir/to/model. For S3, the path should be either virtual-hosted-style or path-style and contains the region information. For examples, take a look at the AWS official documentation.

Implementation Ⅱ

Arguments

  • sparse_embedding_files_map: Dict[str, str], the sparse embedding file will be loaded by the embedding layer with the specified sparse embedding name. There is NO default value and it should be specified by users.

Example:

model.add(hugectr.SparseEmbedding(embedding_type = hugectr.Embedding_t.DistributedSlotSparseEmbeddingHash,
                            workspace_size_per_gpu_in_mb = 23,
                            embedding_vec_size = 1,
                            combiner = "sum",
                            sparse_embedding_name = "sparse_embedding2",
                            bottom_name = "wide_data",
                            optimizer = optimizer))
model.add(hugectr.SparseEmbedding(embedding_type = hugectr.Embedding_t.DistributedSlotSparseEmbeddingHash,
                            workspace_size_per_gpu_in_mb = 358,
                            embedding_vec_size = 16,
                            combiner = "sum",
                            sparse_embedding_name = "sparse_embedding1",
                            bottom_name = "deep_data",
                            optimizer = optimizer))
# ...
model.load_sparse_weights(["wdl_0_sparse_4000.model", "wdl_1_sparse_4000.model"]) # load models for both embedding layers
model.load_sparse_weights({"sparse_embedding1": "wdl_1_sparse_4000.model"}) # or load the model for one embedding layer

load_sparse_optimizer_states method

hugectr.Model.load_sparse_optimizer_states()

This method load the sparse optimizer states from the saved sparse optimizer states files.

Implementation Ⅰ

Arguments

  • sparse_opt_states_files: List[str], the sparse optimizer states files from which the sparse optimizer states will be loaded. The number of files should equal to that of the sparse embedding layers in the model. There is NO default value and it should be specified by users. Remote file systems(HDFS and S3) are also supported. For example, for HDFS, the path can be hdfs://localhost:9000/dir/to/model. For S3, the path should be either virtual-hosted-style or path-style and contains the region information. For examples, take a look at the AWS official documentation.

Implementation Ⅱ

Arguments

  • sparse_opt_states_files_map: Dict[str, str], the sparse optimizer states file will be loaded by the embedding layer with the specified sparse embedding name. There is NO default value and it should be specified by users.


freeze_dense method

hugectr.Model.freeze_dense()

This method takes no extra arguments and freezes the dense weights of the model. Users can use this method when they want to fine-tune the sparse weights.


freeze_embedding method

hugectr.Model.freeze_embedding()

Implementation Ⅰ: freeze the weights of all the embedding layers. This method takes no extra arguments and freezes the sparse weights of the model. Users can use this method when they only want to train the dense weights.

Implementation Ⅱ: freeze the weights of a specific embedding layer. Please refer to Section 3.4 of HugeCTR Criteo Notebook for the usage.

Arguments

  • embedding_name: String, the name of the embedding layer.

Example:

model.add(hugectr.SparseEmbedding(embedding_type = hugectr.Embedding_t.DistributedSlotSparseEmbeddingHash,
                            workspace_size_per_gpu_in_mb = 23,
                            embedding_vec_size = 1,
                            combiner = "sum",
                            sparse_embedding_name = "sparse_embedding2",
                            bottom_name = "wide_data",
                            optimizer = optimizer))
model.add(hugectr.SparseEmbedding(embedding_type = hugectr.Embedding_t.DistributedSlotSparseEmbeddingHash,
                            workspace_size_per_gpu_in_mb = 358,
                            embedding_vec_size = 16,
                            combiner = "sum",
                            sparse_embedding_name = "sparse_embedding1",
                            bottom_name = "deep_data",
                            optimizer = optimizer))
# ...
model.freeze_embedding() # freeze all the embedding layers
model.freeze_embedding("sparse_embedding1") # or free a specific embedding layer

unfreeze_dense method

hugectr.Model.unfreeze_dense()

This method takes no extra arguments and unfreezes the dense weights of the model.


unfreeze_embedding method

hugectr.Model.unfreeze_embedding()

Implementation Ⅰ: unfreeze the weights of all the embedding layers. This method takes no extra arguments and unfreezes the sparse weights of the model.

Implementation Ⅱ: unfreeze the weights of a specific embedding layer.

Arguments

  • embedding_name: String, the name of the embedding layer.


reset_learning_rate_scheduler method

hugectr.Model.reset_learning_rate_scheduler()

This method resets the learning rate scheduler of the model. Users can use this method when they want to fine-tune the model weights.

Arguments

  • base_lr: The base learning rate for the internal learning rate scheduler within Model instance. There is NO default value and it should be specified by users.

  • warmup_steps: The warmup steps for the internal learning rate scheduler within Model instance. The default value is 1.

  • decay_start: The step at which the learning rate decay starts for the internal learning rate scheduler within Model instance. The default value is 0.

  • decay_steps: The number of steps of the learning rate decay for the internal learning rate scheduler within Model instance. The default value is 1.

  • decay_power: The power of the learning rate decay for the internal learning rate scheduler within Model instance. The default value is 2.

  • end_lr: The final learning rate for the internal learning rate scheduler within Model instance. The default value is 0.


set_source method

hugectr.Model.set_source()

The set_source method can set the data source and keyset files under epoch mode training. This overloaded method has two implementations.

Implementation Ⅰ: only valid when repeat_dataset is False and use_embedding_training_cache is True.

Arguments

  • source: List[str], the training dataset source. It can be specified with several file lists, e.g., source = ["file_list.1.txt", "file_list.2.txt"]. There is NO default value and it should be specified by users.

  • keyset: List[str], the keyset files. It should be corresponding to the source. For example, we can specify source = ["file_list.1.txt", "file_list.2.txt"] and source = ["file_list.1.keyset", "file_list.2.keyset"], which have a one-to-one correspondence. There is NO default value and it should be specified by users.

  • eval_source: String, the evaluation dataset source. There is NO default value and it should be specified by users.

Implementation Ⅱ: only valid when repeat_dataset is False and use_embedding_training_cache is False.

Arguments

  • source: String, the training dataset source. For Norm or Parquet dataset, it should be the file list of training data. For Raw dataset, it should be a single training file. There is NO default value and it should be specified by users.

  • eval_source: String, the evaluation dataset source. For Norm or Parquet dataset, it should be the file list of evaluation data. For Raw dataset, it should be a single evaluation file. There is NO default value and it should be specified by users.

Low-level Training API

For HugeCTR low-level training API, the core data structures are basically the same as the high-level training API. On this basis, we expose the internal LearningRateScheduler, DataReader and EmbeddingTrainingCache within the Model, and provide some low-level training methods as well.HugeCTR currently supports both epoch mode training and non-epoch mode training for dataset in Norm and Raw formats, and only supports non-epoch mode training for dataset in Parquet format. While introducing the API usage, we will elaborate how to employ these two modes of training.

LearningRateScheduler

get_next method

hugectr.LearningRateScheduler.get_next()

This method takes no extra arguments and returns the learning rate to be used for the next iteration.

DataReader

set_source method

hugectr.DataReader32.set_source()
hugectr.DataReader64.set_source()

The set_source method of DataReader currently supports the dataset in Norm and Raw formats, and should be used in epoch mode training. When the data reader reaches the end of file for the current training data or evaluation data, this method can be used to re-specify the training data file or evaluation data file.

Arguments

  • file_name: The file name of the new training source or evaluation source. For Norm format dataset, it takes the form of file_list.txt. For Raw format dataset, it appears as data.bin. The default value is '', which means that the data reader will reset to the beginning of the current data file.


is_eof method

hugectr.DataReader32.is_eof()
hugectr.DataReader64.is_eof()

This method takes no extra arguments and returns whether the data reader has reached the end of the current source file.

EmbeddingTraingCache

update method

hugectr.EmbeddingTraingCache.update()

The update method of EmbeddingTraingCache currently supports Norm format datasets. Using this method requires that a series of file lists and the corresponding keyset files are generated at the same time when preprocessing the original data to Norm format. This method gives you the ability to load a subset of an embedding table into the GPU in a coarse grained, on-demand manner during the training stage. Please refer to HugeCTR Embedding Traing Cache if you want to get detailed information about EmbeddingTraingCache.

Arguments

  • keyset_file or keyset_file_list: This method is an overloaded method that can accept str or List[str] as an argument. For the model with multiple embedding tables, if the keyset of each embedding table is not separated when generating the keyset files, then pass in the keyset_file. If the keyset of each embedding table has been separated when generating keyset files, you need to pass in the keyset_file_list, the size of which should equal to the number of embedding tables.

Model

get_learning_rate_scheduler method

hugectr.Model.get_learning_rate_scheduler()

hugectr.Model.get_learning_rate_scheduler generates and returns the LearningRateScheduler object of the model instance. When the SGD optimizer is adopted for training, the returned object can obtain the dynamically changing learning rate according to the warmup_steps, decay_start and decay_steps configured in the hugectr.CreateSolver method. Refer to SGD Optimizer and Learning Rate Scheduling) if you want to get detailed information about LearningRateScheduler.


get_embedding_training_cache method

hugectr.Model.get_embedding_training_cache()

This method takes no extra arguments and returns the EmbeddingTrainingCache object.


get_data_reader_train method

hugectr.Model.get_data_reader_train()

This method takes no extra arguments and returns the DataReader object that reads the training data.


get_data_reader_eval method

hugectr.Model.get_data_reader_eval()

This method takes no extra arguments and returns the DataReader object that reads the evaluation data.


start_data_reading method

hugectr.Model.start_data_reading()

This method takes no extra arguments and should be used if and only if it is under the non-epoch mode training. The method starts the train_data_reader and eval_data_reader before entering the training loop.


set_learning_rate method

hugectr.Model.set_learning_rate()

This method is used together with the get_next method of LearningRateScheduler and sets the learning rate for the next training iteration.

Arguments

  • lr: Float, the learning rate to be set。


train method

hugectr.Model.train()

This method takes no extra arguments and executes one iteration of the model weights based on one minibatch of training data.


get_current_loss method

hugectr.Model.get_current_loss()

This method takes no extra arguments and returns the loss value for the current iteration.


eval method

hugectr.Model.eval()

This method takes no arguments and calculates the evaluation metrics based on one minibatch of evaluation data.


get_eval_metrics method

hugectr.Model.get_eval_metrics()

This method takes no extra arguments and returns the average evaluation metrics of several minibatches of evaluation data.


get_incremental_model method

updated_model = hugectr.Model.get_incremental_model()

This method is only supported in Embedding Training Cache and returns the updated embedding table since the last time calling this method to updated_model. Note that updated_model only stores the embedding features being touched instead of the whole table.

When training with multi-node, the updated_model returned in each node doesn’t have duplicated embedding features, and the aggregations of updated_model from each node form the complete updated sparse model.

The length of updated_model is equal to the number of embedding tables in your model, e.g., length(updated_model)==2 for the wdl model. Each element in updated_model is a pair of NumPy arrays: a 1-D array stores keys in long long format, and another 2-D array stores embedding vectors in float format, where the leading dimension is the embedding vector size. E.g., updated_model[0][0] stores keys, and updated_model[0][1] stores the embedding vectors corresponding to keys in updated_model[0][0].


dump_incremental_model_2kafka method

hugectr.Model.dump_incremental_model_2kafka()

This method is only supported in Embedding Training Cache. It with post the updated embedding table to Kafka as user specified.

Please NOTE that is method can not be used together with the get_incremental_model method. Only one of these two methods could be used for dumping the incremental model.


save_params_to_files method

hugectr.Model.save_params_to_files()

This method save the model parameters to files. If Embedding Training Cache is utilized, this method will save sparse weights, dense weights and dense optimizer states. Otherwise, this method will save sparse weights, sparse optimizer states, dense weights and dense optimizer states.

The stored sparse model can be used for both the later training and inference cases. Each sparse model will be dumped as a separate folder that contains two files (key, emb_vector) for the DistributedSlotEmbedding or three files (key, slot_id, emb_vector) for the LocalizedSlotEmbedding. Details of these files are:

  • key: The unique keys appeared in the training data. All keys are stored in long long format, and HugeCTR will handle the datatype conversion internally for the case when i64_input_key = False.

  • slot_id: The key distribution info internally used by the LocalizedSlotEmbedding.

  • emb_vector: The embedding vectors corresponding to keys stored in the key file.

Note that the key, slot id, and embedding vector are stored in the sparse model in the same sequence, so both the nth slot id in slot_id file and the nth embedding vector in the emb_vector file are mapped to the nth key in the key file.

Arguments

  • prefix: String, the prefix of the saved files for model weights and optimizer states. There is NO default value and it should be specified by users. Remote file systems(HDFS and S3) are also supported. For example, for HDFS, the prefix can be hdfs://localhost:9000/dir/to/model. For S3, the prefix should be either virtual-hosted-style or path-style and contains the region information. For examples, take a look at the AWS official documentation. Please note that dumping models to remote file system when enabled MPI is not supported yet.

  • iter: Integer, the current number of iterations, which will be the suffix of the saved files for model weights and optimizer states. The default value is 0.


check_out_tensor method

hugectr.Model.check_out_tensor()

This method check out the tensor values for the latest training or evaluation iteration. The tensor values will be returned via a numpy array that has the same dimensions as the tensor. The data type of returned numpy array will always be float32, while the data type of the tensor can be float32 or float16 depending on use_mixed_precision. Please NOTE that separate tensors are used for HugeCTR training and evaluation flows, which needs to be specified as an argument of the method. This method can be helpful for debugging and verifying the correctness, given that the values of intermediate tensors can be easily checked out.

Arguments

  • tensor_name: String, the name of the tensor that needs to be checked out. It should be within the names that are specified for tensors when creating the model graph using model.add.

  • tensor_type: hugectr.Tensor_t, the flow that the tensor belongs to, i.e., the training flow or the evaluation flow. The supported types are hugectr.Tensor_t.Train and hugectr.Tensor_t.Evaluate. If hugectr.Tensor_t.Train is specified, the gradients during backward propagation of the latest training iteration will be returned. If hugectr.Tensor_t.Evaluate is specified, the results during forward propagation of the latest evaluation iteration will be returned.

Example:

solver = hugectr.CreateSolver(max_eval_batches = 1280,
                              batchsize_eval = 1024,
                              batchsize = 4096,
                              lr = 0.001,
                              vvgpu = [[0]],
                              repeat_dataset = True)
...
model.add(hugectr.Input(label_dim = 1, label_name = "label",
                        dense_dim = 13, dense_name = "dense",
                        data_reader_sparse_param_array =
                        [hugectr.DataReaderSparseParam("data1", 1, True, 26)]))
model.add(hugectr.SparseEmbedding(embedding_type = hugectr.Embedding_t.DistributedSlotSparseEmbeddingHash,
                           workspace_size_per_gpu_in_mb = 75,
                           embedding_vec_size = 16,
                           combiner = "sum",
                           sparse_embedding_name = "sparse_embedding1",
                           bottom_name = "data1",
                           optimizer = optimizer))
...
model.add(hugectr.DenseLayer(layer_type = hugectr.Layer_t.InnerProduct,
                           bottom_names = ["concat1"],
                           top_names = ["fc1"],
                           num_output=1024))
...
model.fit(...)
# Return a numpy array of (4096, 26, 16)
sparse_embedding1_train_flow = model.check_out_tensor("sparse_embedding1", hugectr.Tensor_t.Train) 
# Return a numpy array of (1024, 1024)
fc1_evaluate_flow = model.check_out_tensor("fc1", hugectr.Tensor_t.Evaluate)

export_predictions method

hugectr.Model.export_predictions()

If you want to export the predictions for specified data, using predict() in inference API is recommended. This method will export the last batch of evaluation prediction and label to file. If the file already exists, the evaluation result will be appended to the end of the file. This method will only export eval_batch_size evaluation result each time. So it should be used in the following way:

for i in range(train_steps):
  # do train
  ...
  # clean prediction / label result file
  prediction_file_in_current_step = "predictions" + str(i)
  if os.path.exists(prediction_file_in_current_step):
    os.remove(prediction_file_in_current_step)
  label_file_in_current_step = "label" + str(i)
  if os.path.exists(label_file_in_current_step):
    os.remove(label_file_in_current_step)
  # do evaluation and export prediction
  for _ in range(solver.max_eval_batches):
    model.eval()
    model.export_predictions(prediction_file_in_current_step, label_file_in_current_step)

Arguments

  • output_prediction_file_name: String, the file to which the evaluation prediction results will be written. The order of the prediction results are the same as that of the labels, but may be different with the order of the samples in the dataset. There is NO default value and it should be specified by users.

  • output_label_file_name: String, the file to which the evaluation labels will be written. The order of the labels are the same as that of the prediction results, but may be different with the order of the samples in the dataset. There is NO default value and it should be specified by users.

Inference API

For HugeCTR inference API, the core data structures are InferenceParams and InferenceModel. They are designed and implemented for the purpose of multi-GPU offline inference. Please refer to HugeCTR Backend if online inference with Triton is needed.

Please NOTE that Inference API requires a configuration JSON file of the model graph, which can derived from the Model.graph_to_json() method. Besides, model_name within CreateSolver should be specified during training in order to correctly dump the JSON file.

InferenceParams

InferenceParams class

hugectr.inference.InferenceParams()

InferenceParams specifies the parameters related to the inference. An InferenceParams instance is required to initialize the InferenceModel instance.

Refer to the HPS Configuration documentation for the parameters.

InferenceModel

InferenceModel class

hugectr.inference.InferenceModel()

InferenceModel is a collection of inference sessions deployed on multiple GPUs, which can leverage Hierarchical Parameter Server and enable concurrent execution. The construction of InferenceModel requires a model configuration file and an InferenceParams instance.

Arguments

  • model_config_path: String, the inference model configuration file (which can be derived from Model.graph_to_json). There is NO default value and it should be specified by users.

  • inference_params: InferenceParams, the InferenceParams object. There is NO default value and it should be specified by users.


predict method

hugectr.inference.InferenceModel.predict()

The predict method of InferenceModel makes predictions based on the dataset of Norm or Parquet format. It will return the 2-D numpy array of the shape (max_batchsize*num_batches, label_dim), whose order is consistent with the sample order in the dataset. If max_batchsize*num_batches is greater than the total number of samples in the dataset, it will loop over the dataset. For example, there are totally 40000 samples in the dataset, max_batchsize equals 4096, num_batches equals 10 and label_dim equals 2. The returned array will be of the shape (40960, 2), of which first 40000 rows should be desired results and the last 960 rows correspond to the first 960 samples in the dataset.

Arguments

  • num_batches: Integer, the number of prediction batches.

  • source: String, the source of prediction dataset. It should be the file list for Norm or Parquet format data.

  • data_reader_type: hugectr.DataReaderType_t, the data reader type. We support hugectr.DataReaderType_t.Norm and hugectr.DataReaderType_t.Parquet.

  • check_type: hugectr.Check_t, the check type for the data source. We currently support hugectr.Check_t.Sum and hugectr.Check_t.Non.

  • slot_size_array: List[int], the cardinality array of input features. It should be consistent with that of the sparse input. We requires this argument for Parquet format data. The default value is an empty list, which is suitable for Norm format data.


evaluate method

hugectr.inference.InferenceModel.evaluate()

The evaluate method of InferenceModel does evaluations based on the dataset of Norm or Parquet format. It requires that the dataset contains the label field. This method returns the AUC value for the specified evaluation batches.

Arguments

  • num_batches: Integer, the number of evaluation batches.

  • source: String, the source of evaluation dataset. It should be the file list for Norm or Parquet format data.

  • data_reader_type: hugectr.DataReaderType_t, the data reader type. We support hugectr.DataReaderType_t.Norm and hugectr.DataReaderType_t.Parquet.

  • check_type: hugectr.Check_t, the check type for the data source. We support hugectr.Check_t.Sum and hugectr.Check_t.Non currently.

  • slot_size_array: List[int], the cardinality array of input features. It should be consistent with that of the sparse input. We requires this argument for Parquet format data. The default value is an empty list, which is suitable for Norm format data.


check_out_tensor method

hugectr.inference.InferenceModel.check_out_tensor()

This method check out the tensor values for the latest inference iteration. The tensor values will be returned via a numpy array that has the same dimensions as the tensor. The data type of returned numpy array will always be float32, while the data type of the tensor can be float32 or float16 depending on use_mixed_precision. This method can be helpful for debugging and verifying the correctness, given that the values of intermediate tensors can be easily checked out.

Arguments

  • tensor_name: String, the name of the tensor that needs to be checked out. It should be within the tensor names of the graph JSON file that is used to create the InferenceModel object.

Example:

model_config = "dcn.json"
inference_params = hugectr.inference.InferenceParams(
    model_name = "dcn",
    max_batchsize = 16,
    hit_rate_threshold = 1.0,
    dense_model_file = "dcn_dense_1000.model",
    sparse_model_files = ["dcn0_sparse_1000.model"],
    deployed_devices = [0,1,2,3],
    use_gpu_embedding_cache = True,
    cache_size_percentage = 0.5,
    i64_input_key = True,
    use_mixed_precision = False,
    use_cuda_graph = True,
    number_of_worker_buffers_in_pool = 16
)
inference_model = hugectr.inference.InferenceModel(model_config, inference_params)
pred = inference_model.predict(
    1,
    EVAL_SOURCE,
    hugectr.DataReaderType_t.Parquet,
    hugectr.Check_t.Non,
    SLOT_SIZE_ARRAY
)
# Return a numpy array of (16, 26, 16), assuming slot_num is 26, embed_vec_size is 16
sparse_embedding1_inference_flow = inference_model.check_out_tensor("sparse_embedding1")

Data Generator API

For HugeCTR data generator API, the core data structures are DataGeneratorParams and DataGenerator. Please refer to data_generator directory in the HugeCTR repository on GitHub to acknowledge how to write Python scripts to generate synthetic dataset and start training HugeCTR model.

DataGeneratorParams class

hugectr.tools.DataGeneratorParams()

DataGeneratorParams specifies the parameters related to the data generation. An DataGeneratorParams instance is required to initialize the DataGenerator instance.

Arguments

  • format: The format for synthetic dataset. The supported types include hugectr.DataReaderType_t.Norm, hugectr.DataReaderType_t.Parquet and hugectr.DataReaderType_t.Raw. There is NO default value and it should be specified by users.

  • label_dim: Integer, the label dimension for synthetic dataset. There is NO default value and it should be specified by users.

  • dense_dim: Integer, the number of dense (or continuous) features for synthetic dataset. There is NO default value and it should be specified by users.

  • num_slot: Integer, the number of sparse feature slots for synthetic dataset. There is NO default value and it should be specified by users.

  • i64_input_key: Boolean, whether to use I64 for input keys for synthetic dataset. If your dataset format is Norm or Paruqet, you can choose the data type of each input key. For the Raw dataset format, only I32 is allowed. There is NO default value and it should be specified by users.

  • source: String, the synthetic training dataset source. For Norm or Parquet dataset, it should be the file list of training data, e.g., source = “file_list.txt”. For Raw dataset, it should be a single training file, e.g., source = “train_data.bin”. There is NO default value and it should be specified by users.

  • eval_source: String, the synthetic evaluation dataset source. For Norm or Parquet dataset, it should be the file list of evaluation data, e.g., source = “file_list_test.txt”. For Raw dataset, it should be a single evaluation file, e.g., source = “test_data.bin”. There is NO default value and it should be specified by users.

  • slot_size_array: List[int], the cardinality array of input features for synthetic dataset. The list length should be equal to num_slot. There is NO default value and it should be specified by users.

  • nnz_array: List[int], the number of non-zero entries in each slot for synthetic dataset. The list length should be equal to num_slot. This argument helps to simulate one-hot or multi-hot encodings. The default value is an empty list and one-hot encoding will be employed then.

  • check_type: The data error detection mechanism. The supported types include hugectr.Check_t.Sum (CheckSum) and hugectr.Check_t.Non (no detection). The default value is hugectr.Check_t.Sum.

  • dist_type: The distribution of the sparse input keys for synthetic dataset. The supported types include hugectr.Distribution_t.PowerLaw and hugectr.Distribution_t.Uniform. The default value is hugectr.Distribution_t.PowerLaw.

  • power_law_type: The specific distribution of power law distribution. The supported types include hugectr.PowerLaw_t.Long (alpha=0.9), hugectr.PowerLaw_t.Medium (alpha=1.1), hugectr.PowerLaw_t.Short (alpha=1.3) and hugectr.PowerLaw_t.Specific (requiring a specific alpha value). This argument is only valid when dist_type is hugectr.Distribution_t.PowerLaw. The default value is hugectr.PowerLaw_t.Specific.

  • alpha: Float, the alpha value for power law distribution. This argument is only valid when dist_type is hugectr.Distribution_t.PowerLaw and power_law_type is hugectr.PowerLaw_t.Specific. The alpha value should be greater than zero and not equal to 1.0. The default value is 1.2.

  • num_files: Integer, the number of training data files that will be generated. This argument is valid when format is hugectr.DataReaderType_t.Norm or hugectr.DataReaderType_t.Parquet. The default value is 128.

  • eval_num_files: Integer, the number of evaluation data files that will be generated. This argument is valid when format is hugectr.DataReaderType_t.Norm or hugectr.DataReaderType_t.Parquet. The default value is 32.

  • num_samples_per_file: Integer, the number of samples per generated data file. This argument is valid when format is hugectr.DataReaderType_t.Norm or hugectr.DataReaderType_t.Parquet. The default value is 40960.

  • num_samples: Integer, the number of samples in the generated single training data file (e.g., train_data.bin). This argument is only valid when format is hugectr.DataReaderType_t.Raw. The default value is 5242880.

  • eval_num_samples: Integer, the number of samples in the generated single evaluation data file (e.g., test_data.bin). This argument is only valid when format is hugectr.DataReaderType_t.Raw. The default value is 1310720.

  • float_label_dense: Boolean, this is only valid when format is hugectr.DataReaderType_t.Raw. If its value is set to True, the label and dense features for each sample are interpreted as float values. Otherwise, they are regarded as integer values while the dense features are preprocessed with log(dense[i] + 1.f). The default value is False.

DataGenerator

DataGenerator class

hugectr.tools.DataGenerator()

DataGenerator provides an API to generate synthetic Norm, Parquet or Raw dataset. The construction of DataGenerator requires a DataGeneratorParams instance.

Arguments

  • data_generator_params: The DataGeneratorParams instance which encapsulates the required parameters for data generation. There is NO default value and it should be specified by users.

generate method

hugectr.tools.DataGenerator.generate()

This method takes no extra arguments and starts to generate the synthetic dataset based on the configurations within data_generator_params.

Data Source API

DataSourceParams class

hugectr.data.DataSourceParams()

DataSourceParams specifies the file system information and the paths to data and model used for training. A DataSourceParams instance is required to initialize the DataSource instance.

Arguments

  • source: hugect.FileSystemType_t, can be Local or HDFS or S3, specifying the file system. Default is hugectr.FileSystemType_t.Local.

  • server: String, the IP address of your file system. For Hadoop cluster(HDFS), it is your namenode. For AWS S3, it is the region. Will be ignored if source is FileSystemType_t.Local. Default is ‘localhost’.

  • port: Integer, the port to listen from your Hadoop server. Will be ignored if source is FileSystemType_t.Local or FileSystemType_t.S3. Default is 9000.