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mindspore/model_zoo/official/cv/inceptionv3
dinglinhe 31ea6fc7f7 update README at model_zoo 4 years ago
..
scripts add inceptionv3 cpu train script 4 years ago
src add inceptionv3 cpu train script 4 years ago
README.md update README at model_zoo 4 years ago
README_CN.md update README at model_zoo 4 years ago
eval.py add inceptionv3 cpu train script 4 years ago
export.py fix GPU device_id bug 4 years ago
mindspore_hub_conf.py add hub for densenet121 and inceptionv3 5 years ago
train.py add inceptionv3 cpu train script 4 years ago

README.md

Contents

InceptionV3 Description

InceptionV3 by Google is the 3rd version in a series of Deep Learning Convolutional Architectures. Inception v3 mainly focuses on burning less computational power by modifying the previous Inception architectures. This idea was proposed in the paper Rethinking the Inception Architecture for Computer Vision, published in 2015.

Paper Min Sun, Ali Farhadi, Steve Seitz. Ranking Domain-Specific Highlights by Analyzing Edited Videos[J]. 2014.

Model architecture

The overall network architecture of InceptionV3 is show below:

Link

Dataset

Dataset used can refer to paper.

  • Dataset size: 125G, 1250k colorful images in 1000 classes
    • Train: 120G, 1200k images
    • Test: 5G, 50k images
  • Data format: RGB images.
    • Note: Data will be processed in src/dataset.py

Dataset used: CIFAR-10

  • Dataset size: 175M, 60,000 32*32 colorful images in 10 classes
    • Train: 146M, 50,000 images
    • Test: 29M, 10,000 images
  • Data format:binary files
    • Note:Data will be processed in src/dataset.py

Features

Mixed Precision(Ascend)

The mixed precision training method accelerates the deep learning neural network training process by using both the single-precision and half-precision data formats, and maintains the network precision achieved by the single-precision training at the same time. Mixed precision training can accelerate the computation process, reduce memory usage, and enable a larger model or batch size to be trained on specific hardware.

For FP16 operators, if the input data type is FP32, the backend of MindSpore will automatically handle it with reduced precision. Users could check the reduced-precision operators by enabling INFO log and then searching ‘reduce precision’.

Environment Requirements

Script description

Script and sample code

.
└─Inception-v3
  ├─README.md
  ├─scripts
    ├─run_standalone_train_cpu.sh             # launch standalone training with cpu platform
    ├─run_standalone_train_gpu.sh             # launch standalone training with gpu platform(1p)
    ├─run_distribute_train_gpu.sh             # launch distributed training with gpu platform(8p)
    ├─run_standalone_train.sh                 # launch standalone training with ascend platform(1p)
    ├─run_distribute_train.sh                 # launch distributed training with ascend platform(8p)
    ├─run_eval_cpu.sh                         # launch evaluation with cpu platform
    ├─run_eval_gpu.sh                         # launch evaluation with gpu platform
    └─run_eval.sh                             # launch evaluating with ascend platform
  ├─src
    ├─config.py                       # parameter configuration
    ├─dataset.py                      # data preprocessing
    ├─inception_v3.py                 # network definition
    ├─loss.py                         # Customized CrossEntropy loss function
    ├─lr_generator.py                 # learning rate generator
  ├─eval.py                           # eval net
  ├─export.py                         # convert checkpoint
  └─train.py                          # train net

Script Parameters

Major parameters in train.py and config.py are:
'random_seed'                # fix random seed
'work_nums'                  # number of workers to read the data
'decay_method'               # learning rate scheduler mode
"loss_scale"                 # loss scale
'batch_size'                 # input batchsize
'epoch_size'                 # total epoch numbers
'num_classes'                # dataset class numbers
'ds_type'                    # dataset type, such as: imagenet, cifar10
'ds_sink_mode'               # whether enable dataset sink mode
'smooth_factor'              # label smoothing factor
'aux_factor'                 # loss factor of aux logit
'lr_init'                    # initiate learning rate
'lr_max'                     # max bound of learning rate
'lr_end'                     # min bound of learning rate
'warmup_epochs'              # warmup epoch numbers
'weight_decay'               # weight decay
'momentum'                   # momentum
'opt_eps'                    # epsilon
'keep_checkpoint_max'        # max numbers to keep checkpoints
'ckpt_path'                  # save checkpoint path
'is_save_on_master'          # save checkpoint on rank0, distributed parameters
'dropout_keep_prob'          # the keep rate, between 0 and 1, e.g. keep_prob = 0.9, means dropping out 10% of input units
'has_bias'                   # specifies whether the layer uses a bias vector.
'amp_level'                  # option for argument `level` in `mindspore.amp.build_train_network`, level for mixed
                             # precision training. Supports [O0, O2, O3].

Training process

Usage

You can start training using python or shell scripts. The usage of shell scripts as follows:

  • Ascend:
# distribute training(8p)
sh scripts/run_distribute_train.sh RANK_TABLE_FILE DATA_PATH
# standalone training
sh scripts/run_standalone_train.sh DEVICE_ID DATA_PATH
  • CPU:
# standalone training
sh scripts/run_standalone_train_cpu.sh DATA_PATH

Notes: RANK_TABLE_FILE can refer to Link, and the device_ip can be got as Link. For large models like InceptionV3, it's better to export an external environment variable export HCCL_CONNECT_TIMEOUT=600 to extend hccl connection checking time from the default 120 seconds to 600 seconds. Otherwise, the connection could be timeout since compiling time increases with the growth of model size.

This is processor cores binding operation regarding the device_num and total processor numbers. If you are not expect to do it, remove the operations taskset in scripts/run_distribute_train.sh

Launch

# training example
  python:
      Ascend: python train.py --dataset_path DATA_PATH --platform Ascend
      CPU: python train.py --dataset_path DATA_PATH --platform CPU

  shell:
      Ascend:
      # distribute training example(8p)
      sh scripts/run_distribute_train.sh RANK_TABLE_FILE DATA_PATH
      # standalone training example
      sh scripts/run_standalone_train.sh DEVICE_ID DATA_PATH

      CPU:
      sh script/run_standalone_train_cpu.sh DATA_PATH

Result

Training result will be stored in the example path. Checkpoints will be stored at . /checkpoint by default, and training log will be redirected to ./log.txt like followings.

Ascend

epoch: 0 step: 1251, loss is 5.7787247
epoch time: 360760.985 ms, per step time: 288.378 ms
epoch: 1 step: 1251, loss is 4.392868
epoch time: 160917.911 ms, per step time: 128.631 ms

CPU

epoch: 1 step: 390, loss is 2.7072601
epoch time: 6334572.124 ms, per step time: 16242.493 ms
epoch: 2 step: 390, loss is 2.5908582
epoch time: 6217897.644 ms, per step time: 15943.327 ms
epoch: 3 step: 390, loss is 2.5612416
epoch time: 6358482.104 ms, per step time: 16303.800 ms
...

Eval process

Usage

You can start training using python or shell scripts. The usage of shell scripts as follows:

  • Ascend:
    sh scripts/run_eval.sh DEVICE_ID DATA_PATH PATH_CHECKPOINT
  • CPU:
    sh scripts/run_eval_cpu.sh DATA_PATH PATH_CHECKPOINT

Launch

# eval example
  python:
      Ascend: python eval.py --dataset_path DATA_PATH --checkpoint PATH_CHECKPOINT --platform Ascend
      CPU: python eval.py --dataset_path DATA_PATH --checkpoint PATH_CHECKPOINT --platform CPU

  shell:
      Ascend: sh scripts/run_eval.sh DEVICE_ID DATA_PATH PATH_CHECKPOINT
      CPU: sh scripts/run_eval_cpu.sh DATA_PATH PATH_CHECKPOINT

checkpoint can be produced in training process.

Result

Evaluation result will be stored in the example path, you can find result like the followings in eval.log.

metric: {'Loss': 1.778, 'Top1-Acc':0.788, 'Top5-Acc':0.942}

Model description

Performance

Evaluation Performance

Parameters Ascend
Model Version InceptionV3
Resource Ascend 910; cpu 2.60GHz, 192cores; memory 755G; OS Euler2.8
uploaded Date 08/21/2020
MindSpore Version 0.6.0-beta
Dataset 1200k images
Batch_size 128
Training Parameters src/config.py
Optimizer RMSProp
Loss Function SoftmaxCrossEntropy
Outputs probability
Loss 1.98
Total time (8p) 11h
Params (M) 103M
Checkpoint for Fine tuning 313M
Model for inference 92M (.onnx file)
Speed 1pc:1050 img/s;8pc:8000 img/s
Scripts inceptionv3 script

Inference Performance

Parameters Ascend
Model Version InceptionV3
Resource Ascend 910; cpu 2.60GHz, 192cores; memory 755G; OS Euler2.8
Uploaded Date 08/22/2020
MindSpore Version 0.6.0-beta
Dataset 50k images
Batch_size 128
Outputs probability
Accuracy ACC1[78.8%] ACC5[94.2%]
Total time 2mins

Description of Random Situation

In dataset.py, we set the seed inside “create_dataset" function. We also use random seed in train.py.

ModelZoo Homepage

Please check the official homepage.

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MindSpore is a new open source deep learning training/inference framework that could be used for mobile, edge and cloud scenarios.

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