Applying my Netflix experience to a real-world problem in the ML and AI world, I will demonstrate a full-featured, open-source, end-to-end TensorFlow Model Training and Deployment System using the latest advancements from Kubernetes, Istio, and TensorFlow. In addition to training and hyper-parameter tuning, our model deployment pipeline will include continuous canary deployments of our TensorFlow Models into a live, hybrid-cloud production environment. This is the holy grail of data science - rapid and safe experiments of ML / AI models directly in production. Following the Successful Netflix Culture that I lived and breathed (https://www.slideshare.net/reed2001/culture-1798664/2-Netflix_CultureFreedom_Responsibility2), I give Data Scientists the Freedom and Responsibility to extend their ML / AI pipelines and experiments safely into production. Offline, batch training and validation is for the slow and weak. Online, real-time training and validation on live production data is for the fast and strong. Learn to be fast and strong by attending this talk. Bio: Chris Fregly is Founder and Research Engineer at PipelineAI, a Streaming Machine Learning and Artificial Intelligence Startup based in San Francisco. He is also an Apache Spark Contributor, a Netflix Open Source Committer, founder of the Global Advanced Spark and TensorFlow Meetup, author of the O’Reilly Training and Video Series titled, "High Performance TensorFlow in Production." Previously, Chris was a Distributed Systems Engineer at Netflix, a Data Solutions Engineer at Databricks, and a Founding Member and Principal Engineer at the IBM Spark Technology Center in San Francisco. http://pipeline.ai

1. HIGH PERFORMANCE TENSORFLOW IN
PRODUCTION WITH GPUS
ODSC CONFERENCE WEST
SAN FRANCISCO, CA, NOV 2017
CHRIS FREGLY, FOUNDER @PIPELINE.AI

2. INTRODUCTIONS: ME
§ Chris Fregly, Founder & Engineer @ PipelineAI
§ Formerly Netflix and Databricks
§ Advanced Spark and TensorFlow Meetup
Please Join Our 50,000+ Members Globally!
Contact Me
chris@pipeline.ai
@cfregly
* San Francisco
* Chicago
* Austin
* Washington DC
* Dusseldorf
* London

3. INTRODUCTIONS: YOU
§ Software Engineer, Data Scientist, Data Engineer, Data Analyst
§ Interested in Optimizing and Deploying TF Models to Production
§ Nice to Have a Working Knowledge of TensorFlow (Not Required)

4. CONTENT BREAKDOWN
50% Training Optimizations (GPUs, Training Pipeline, JIT)
50% Prediction Optimizations (AOT Compile, TF Serving)
Why Heavy Focus on Model Prediction vs. Just Training?
10s of Data Scientists <<< Millions of App Users
Training
Boring & Batch
Prediction
Exciting & Real-Time!!

5. AGENDA
Part 0: Latest PipelineAI Research
Part 1: Optimize TensorFlow Model Training
Part 2: Optimize TensorFlow Model Serving

6. 100% OPEN SOURCE CODE
§ https://github.com/PipelineAI/pipeline/
§ Please 🌟 this GitHub Repo!
§ All slides, code, notebooks, and Docker images here:
https://github.com/PipelineAI/pipeline/tree/master/gpu.ml
https://github.com/rviscomi/red-dwarf

7. HANDS-ON EXERCISES
§ Combo of Jupyter Notebooks and Command Line
§ Command Line through Jupyter Terminal
§ Some Exercises Based on Experimental Features
You May See Errors. Stay Calm. You Will Be OK!!

8. PIPELINE.AI OVERVIEW
400,000 Docker Downloads
50,000 Registered Users for
PipelineAI GA Release
2,000 GitHub Stars
15 Enterprise Beta Users

9. AGENDA
Part 0: Latest PipelineAI Research
§ Package, Deploy, and Tune Both Model + Runtime
§ Deploy Models and Experiments Safely to Prod
§ Compare Models Both Offline and Online
§ Auto-Shift Traffic to Winning Model or Cloud

10. PACKAGE MODEL + RUNTIME AS ONE
§ Package Model + Runtime into Immutable Docker Image
§ Same Environment: Local, Dev, and Prod
§ No Dependency Surprises in Production
§ Deploy and Tune Model + Runtime Together
pipeline predict-server-build --model-type=tensorflow
--model-name=mnist
--model-tag=”b"
--model-path=./models/tensorflow/mnist
Package
Model Server
pipeline predict-server-push --model-type=tensorflow
--model-name=mnist
--model-tag=”b”
Push Image
To Docker

11. TUNE MODEL + RUNTIME TOGETHER
§ Try Different Model Hyper-Parameters + Runtime Configs
§ Even Different Runtimes: TF Serving, TensorRT
§ Auto-Quantize Model Weights + Activations
§ Auto-Fuse Neural Network Layers Together
§ Generate Native CPU + GPU Code
pipeline predict-server-start --model-type=tensorflow
--model-name=mnist
--model-tag=”b"
Start
Model Server

12. LOAD TEST MODEL + RUNTIME LOCALLY
§ Perform Mini-Load Test on Local Model Server
§ Provides Immediate Feedback on Prediction Performance
§ Relative Performance Compared to Other Variations
§ No Need to Deploy to Test or Prod for Prediction Metrics
§ See Where Time is Being Spent During Prediction
pipeline predict --model-server-url=http://localhost:6969
--model-type=tensorflow
--model-name=mnist
--model-tag=”b”
--test-request-concurrency=10000
Load Test
Model Server

13. RUNTIME OPTION: NVIDIA TENSOR-RT
§ GPU-Optimized Prediction Runtime
§ Alternative to TensorFlow Serving
§ Post-Training Model Optimizations
§ Similar to TF Graph Transform Tool
§ PipelineAI Supports TensorRT!

14. AGENDA
Part 0: Latest PipelineAI Research
§ Package, Deploy, and Tune Both Model + Runtime
§ Deploy Models and Experiments Safely to Prod
§ Compare Models Both Offline and Online
§ Auto-Shift Traffic to Winning Model or Cloud

15. DEPLOY MODELS SAFELY TO PROD
§ Deploy with 1-Click from Jupyter or CLI
§ Deploy to 1-2% Traffic Split or Shadow
§ Tear-Down or Rollback Quickly
pipeline predict-cluster-start --model-type=tensorflow
--model-name=mnist
--model-tag=”b”
--traffic-split=“0.02”
Start Model
Cluster B in Prod
pipeline predict-cluster-start --model-type=tensorflow
--model-name=mnist
--model-tag=”c”
--traffic-split=“0.01”
Start Model
Cluster C in Prod
pipeline predict-cluster-start --model-type=tensorflow
--model-name=mnist
--model-tag=”a”
--traffic-split=“0.97”
Start Model
Cluster A in Prod

16. DEPLOY EXPERIMENTS SAFELY TO PROD
§ Create Experiments Directly from Jupyter or Command Line
pipeline experiment-add --experiment-name=my_experiment
--model-type=tensorflow
--model-name=mnist
--model-tag=“a”
--traffic-split=“97%”
CLI
Drag n’
Drop
pipeline experiment-start --experiment-name=my_experiment
--traffic-shadow=“20%”
pipeline experiment-add --experiment-name=my_experiment
--model-type=tensorflow
--model-name=mnist
--model-tag=“b”
--traffic-split=“2%”
pipeline experiment-add --experiment-name=my_experiment
--model-type=tensorflow
--model-name=mnist
--model-tag=“c”
--traffic-split=“1%”
Add Models
to Experiment
With 97%,2%,1%
Traffic Split
Start Experiment
On 20% Shadowed
Production Traffic
1-Click

17. AGENDA
Part 0: Latest PipelineAI Research
§ Package, Deploy, and Tune Both Model + Runtime
§ Deploy Models and Experiments Safely to Prod
§ Compare Models Both Offline and Online
§ Auto-Shift Traffic to Winning Model or Cloud

18. COMPARE MODELS OFFLINE & ONLINE
§ Offline Metrics
§ Validation Accuracy
§ Training Accuracy
§ Online Real-Time Metrics
§ Prediction Precision
§ Latency & Throughput

19. PREDICTION PROFILING AND TUNING
§ Pinpoint Performance Bottlenecks
§ Fine-Grained Prediction Metrics
§ Three (3) Logic Prediction Steps
1. transform_request()
2. predict()
3. transform_response()

20. VIEW REAL-TIME PREDICTION STREAM
§ Visually Compare Real-Time Predictions
Feature
Inputs
Prediction
Confidence

21. CONTINUOUS MODEL TRAINING
§ Identify and Fix Borderline Predictions (~50-50% Confidence)
§ Fix Along Class Boundaries
§ Retrain on New Labeled Data
§ Game-ify Labeling Process
§ Enables Crowd Sourcing

22. AGENDA
Part 0: Latest PipelineAI Research
§ Package, Deploy, and Tune Both Model + Runtime
§ Deploy Models and Experiments Safely to Prod
§ Compare Models Both Offline and Online
§ Auto-Shift Traffic to Winning Model or Cloud

23. SHIFT TRAFFIC TO MAX(REVENUE)
§ Shift Traffic to Winning Model using AI Bandit Algorithms

24. SHIFT TRAFFIC TO MIN(CLOUD COST)
§ Real-Time Cost Per Prediction
§ Across Clouds & On-Premise
§ Bandit-based Explore/Exploit

25. AGENDA
Part 0: Latest PipelineAI Research
Part 1: Optimize TensorFlow Model Training
Part 2: Optimize TensorFlow Model Serving

26. AGENDA
Part 1: Optimize TensorFlow Model Training
§ GPUs and TensorFlow
§ Train, Inspect, and Debug TensorFlow Models
§ TensorFlow Distributed Model Training on a Cluster
§ Optimize Training with JIT XLA Compiler

27. EVERYBODY GETS A GPU!

28. SETUP ENVIRONMENT
§ Step 1: Browse to the following:
http://allocator.community.pipeline.ai/allocate
§ Step 2: Browse to the following:
http://<ip-address>
§ Step 3: Browse around.
I will provide a Jupyter Username/Password soon.
Need Help?
Use the Chat!

29. VERIFY SETUP
http://<ip-address>
Any username,
Any password!

30. LET’S EXPLORE OUR ENVIRONMENT
§ Navigate to the following notebook:
01_Explore_Environment
§ https://github.com/PipelineAI/pipeline/tree/master/
gpu.ml/notebooks

31. PULSE CHECK

32. BREAK
§ Please 🌟 this GitHub Repo!
§ All slides, code, notebooks, and Docker images here:
https://github.com/PipelineAI/pipeline/tree/master/gpu.ml
Need Help?
Use the Chat!

33. SETTING UP TENSORFLOW WITH GPUS
§ Very Painful!
§ Especially inside Docker
§ Use nvidia-docker
§ Especially on Kubernetes!
§ Use Kubernetes 1.8+
§ http://pipeline.ai for GitHub + DockerHub Links

34. GPU HALF-PRECISION SUPPORT
§ FP32 is “Full Precision”, FP16 is “Half Precision”
§ Supported by Pascal P100 (2016) and Volta V100 (2017)
§ Half-Precision is OK for Approximate Deep Learning Use Cases
§ Fit Two(2) FP16’s into FP32 GPU Cores for 2x Throughput!
You Can Set
TF_FP16_MATMUL_USE_FP32_COMPUTE=0
on GPU w/ Compute Capability(CC) 5.3+

35. VOLTA V100 (2017) VS. PASCAL P100 (2016)
§ 84 Streaming Multiprocessors (SM’s)
§ 5,376 GPU Cores
§ 672 Tensor Cores (ie. Google TPU)
§ Mixed FP16/FP32 Precision
§ More Shared Memory
§ New L0 Instruction Cache
§ Faster L1 Data Cache
§ V100 vs. P100 Performance
§ 12x TFLOPS @ Peak Training
§ 6x Inference Throughput

36. V100 AND CUDA 9
§ Independent Thread Scheduling - Finally!!
§ Similar to CPU fine-grained thread synchronization semantics
§ Allows GPU to yield execution of any thread
§ Still Optimized for SIMT (Same Instruction Multiple Thread)
§ SIMT units automatically scheduled together
§ Explicit Synchronization
P100 V100

37. GPU CUDA PROGRAMMING
§ Barbaric, But Fun Barbaric
§ Must Know Hardware Very Well
§ Hardware Changes are Painful
§ Use the Profilers & Debuggers

38. CUDA STREAMS
§ Asynchronous I/O Transfer
§ Overlap Compute and I/O
§ Keeps GPUs Saturated
§ Fundamental to Queue Framework in TensorFlow

39. LET’S SEE WHAT THIS THING CAN DO!
§ Navigate to the following notebook:
01a_Explore_GPU
01b_Explore_Numba
§ https://github.com/PipelineAI/pipeline/tree/master/
gpu.ml/notebooks

40. AGENDA
Part 1: Optimize TensorFlow Model Training
§ GPUs and TensorFlow
§ Train, Inspect, and Debug TensorFlow Models
§ TensorFlow Distributed Model Training on a Cluster
§ Optimize Training with JIT XLA Compiler

41. TRAINING TERMINOLOGY
§ Tensors: N-Dimensional Arrays
§ ie. Scalar, Vector, Matrix
§ Operations: MatMul, Add, SummaryLog,…
§ Graph: Graph of Operations (DAG)
§ Session: Contains Graph(s)
§ Feeds: Feed Inputs into Placeholder
§ Fetches: Fetch Output from Operation
§ Variables: What We Learn Through Training
§ aka “Weights”, “Parameters”
§ Devices: Hardware Device (GPU, CPU, TPU, ...)
-TensorFlow-
Trains
Variables
-User-
Fetches
Outputs
-User-
Feeds
Inputs
-TensorFlow-
Performs
Operations
-TensorFlow-
Flows
Tensors
with tf.device(“/cpu:0,/gpu:15”):

42. TENSORFLOW SESSION
Session
graph: GraphDef
Variables:
“W” : 0.328
“b” : -1.407
Variables are
Randomly
Initialized, then
Periodically
Checkpointed
GraphDef is
Created
During
Training, then
Frozen for
Inference

43. TENSORFLOW MODEL
§ MetaGraph
§ Combines GraphDef and Metadata
§ GraphDef
§ Architecture of your model (nodes, edges)
§ Metadata
§ Asset: Accompanying assets to your model
§ SignatureDef: Maps external : internal tensors
§ Variables
§ Stored separately during training (checkpoint)
§ Allows training to continue from any checkpoint
§ Variables are “frozen” into Constants when preparing for inference
GraphDef
x
W
mul add
b
MetaGraph
Metadata
Assets
SignatureDef
Tags
Version
Variables:
“W” : 0.328
“b” : -1.407

44. BATCH NORMALIZATION (2015)
§ Each Mini-Batch May Have Wildly Different Distributions
§ Normalize per Batch (and Layer)
§ Faster Training, Learns Quicker
§ Final Model is More Accurate
§ TensorFlow is already on 2nd Generation Batch Algorithm
§ First-Class Support for Fusing Batch Norm Layers
§ Final mean + variance Are Folded Into Our Graph Later
-- (Almost)Always Use Batch Normalization! --
z = tf.matmul(a_prev, W)
a = tf.nn.relu(z)
a_mean, a_var = tf.nn.moments(a, [0])
scale = tf.Variable(tf.ones([depth/channels]))
beta = tf.Variable(tf.zeros ([depth/channels]))
bn = tf.nn.batch_normalizaton(a, a_mean, a_var,
beta, scale, 0.001)

45. DROP OUT (2014)
§ Training Technique
§ Prevents Overfitting
§ Probabilistically Combine Diff Neural Architectures
§ Expressed as Probability Percentage (ie. 50%)
§ Weights are Boosted During Validation / Prediction
Training
Validation
& Prediction

46. OPTIMIZE GRAPH EXECUTION ORDER
§ https://github.com/yaroslavvb/stuff
"Linearize” Causes
TF to Minimize
Graph
Memory Usage.
This is Useful on
Single GPU with
Relatively Low
RAM.

47. EXTEND EXISTING DATA PIPELINES
§ Data Processing
§ HDFS/Hadoop
§ Spark
§ Containers
§ Docker
§ Schedulers
§ Kubernetes
§ Mesos
<dependency>
<groupId>org.tensorflow</groupId>
<artifactId>tensorflow-hadoop</artifactId>
</dependency>
https://github.com/tensorflow/ecosystem

48. DON’T USE FEED_DICT!!
§ feed_dict Requires Python <-> C++ Serialization
§ Not Optimized for Production Ingestion Pipelines
§ Retrieves Next Batch After Current Batch is Done
§ Single-Threaded, Synchronous
§ CPUs/GPUs Not Fully Utilized!
§ Use Queue or Dataset API
sess.run(train_step, feed_dict={…}

49. QUEUES
§ More than traditional Queue
§ Uses CUDA Streams
§ Perform I/O, pre-processing, cropping, shuffling, …
§ Pull from HDFS, S3, Google Storage, Kafka, ...
§ Combine many small files into large TFRecord files
§ Use CPUs to free GPUs for compute
§ Helps saturate CPUs and GPUs

50. QUEUE CAPACITY PLANNING
§ batch_size
§ # examples / batch (ie. 64 jpg)
§ Limited by GPU RAM
§ num_processing_threads
§ CPU threads pull and pre-process batches of data
§ Limited by CPU Cores
§ queue_capacity
§ Limited by CPU RAM (ie. 5 * batch_size)

51. DETECT UNDERUTILIZED CPUS, GPUS
§ Instrument training code to generate “timelines”
§ Analyze with Google Web
Tracing Framework (WTF)
§ Monitor CPU with `top`, GPU with `nvidia-smi`
http://google.github.io/tracing-framework/
from tensorflow.python.client import timeline
trace =
timeline.Timeline(step_stats=run_metadata.step_stats)
with open('timeline.json', 'w') as trace_file:
trace_file.write(
trace.generate_chrome_trace_format(show_memory=True))

52. LET’S FEED DATA WITH A QUEUE
§ Navigate to the following notebook:
02_Feed_Queue_HDFS
§ https://github.com/PipelineAI/pipeline/tree/master/
gpu.ml/notebooks

53. PULSE CHECK

54. BREAK
§ Please 🌟 this GitHub Repo!
§ All slides, code, notebooks, and Docker images here:
https://github.com/PipelineAI/pipeline/tree/master/gpu.ml
Need Help?
Use the Chat!

55. LET’S TRAIN A MODEL (CPU)
§ Navigate to the following notebook:
03_Train_Model_CPU
§ https://github.com/PipelineAI/pipeline/tree/master/
gpu.ml/notebooks

56. LET’S TRAIN A MODEL (GPU)
§ Navigate to the following notebook:
03a_Train_Model_GPU
§ https://github.com/PipelineAI/pipeline/tree/master/
gpu.ml/notebooks

57. TENSORFLOW DEBUGGER
§ Step through Operations
§ Inspect Inputs and Outputs
§ Wrap Session in Debug Session
sess = tf.Session(config=config)
sess =
tf_debug.LocalCLIDebugWrapperSession(sess)

58. LET’S DEBUG A MODEL
§ Navigate to the following notebook:
04_Debug_Model
§ https://github.com/PipelineAI/pipeline/tree/master/
gpu.ml/notebooks

59. AGENDA
Part 1: Optimize TensorFlow Model Training
§ GPUs and TensorFlow
§ Train, Inspect, and Debug TensorFlow Models
§ TensorFlow Distributed Model Training on a Cluster
§ Optimize Training with JIT XLA Compiler

60. SINGLE NODE, MULTI-GPU TRAINING
§ cpu:0
§ By default, all CPUs
§ Requires extra config to target a CPU
§ gpu:0..n
§ Each GPU has a unique id
§ TF usually prefers a single GPU
§ xla_cpu:0, xla_gpu:0..n
§ “JIT Compiler Device”
§ Hints TensorFlow to attempt JIT Compile
with tf.device(“/cpu:0”):
with tf.device(“/gpu:0”):
with tf.device(“/gpu:1”):
GPU 0 GPU 1

61. DISTRIBUTED, MULTI-NODE TRAINING
§ TensorFlow Automatically Inserts Send and Receive Ops into Graph
§ Parameter Server Synchronously Aggregates Updates to Variables
§ Nodes with Multiple GPUs will Pre-Aggregate Before Sending to PS
Worker0 Worker0
Worker1
Worker
0
Worker
1
Worker
2
gpu0 gpu1
gpu2 gpu3
gpu0 gpu1
gpu2 gpu3
gpu0 gpu1
gpu2 gpu3
gpu0
gpu1
gpu0
gpu0
Single
Node
Multiple
Nodes

62. DATA PARALLEL VS MODEL PARALLEL
§ Data Parallel (“Between-Graph Replication”)
§ Send exact same model to each device
§ Each device operates on partition of data
§ ie. Spark sends same function to many workers
§ Each worker operates on their partition of data
§ Model Parallel (“In-Graph Replication”)
§ Send different partition of model to each device
§ Each device operates on all data
Very Difficult!, But
Required for Large Models.
(GPU RAM Limitation)

63. SYNCHRONOUS VS. ASYNCHRONOUS
§ Synchronous
§ Nodes compute gradients
§ Nodes update Parameter Server (PS)
§ Nodes sync on PS for latest gradients
§ Asynchronous
§ Some nodes delay in computing gradients
§ Nodes don’t update PS
§ Nodes get stale gradients from PS
§ May not converge due to stale reads!

64. CHIEF WORKER
§ Worker Task 0 is Usually the Chief
§ Task 0 is guaranteed to exist
§ Performs Maintenance Tasks
§ Writes log summaries
§ Instructs PS to checkpoint vars
§ Performs PS health checks
§ (Re-)Initialize variables at (re-)start of training

65. NODE AND PROCESS FAILURES
§ Checkpoint to Persistent Storage (HDFS, S3)
§ Use MonitoredTrainingSession and Hooks
§ Use a Good Cluster Orchestrator (ie. Kubernetes,Mesos)
§ Understand Failure Modes and Recovery States
Stateless, Not Bad: Training Continues Stateful, Bad: Training Must Stop Dios Mio! Long Night Ahead…

66. USE ESTIMATOR AND EXPERIMENT APIS
§ Simplify Model Building
§ Provide Clear Path to Production
§ Enable Rapid Model Experiments
§ Provide Flexible Parameter Tuning
§ Enable Downstream Optimizing & Serving Infra( )
§ Nudge Users to Best Practices Through Opinions
§ Provide Hooks/Callbacks to Override Opinions
§ Unified API for Local and Distributed TensorFlow
https://arxiv.org/pdf/1708.02637.pdf

67. ESTIMATOR API
§ “Train-to-Serve” Design
§ Create Custom - or Use a Canned Estimator
§ Hides Session, Graph, Layers, Iterative Loops (Train, Eval, Predict)
§ Hooks for All Phases of Model Training and Evaluation
§ Load Input: input_fn()
§ Train: model_fn() and train()
§ Evaluate: evaluate()
§ Save and Export: export_savedmodel()
§ Predict: predict() Uses sess.run() Slow Predictions!
Example:
https://github.com/GoogleCloudPlatform/
cloudml-samples/blob/master/census/
customestimator/

68. LAYERS API
§ Standalone Layer or Entire Sub-Graphs
§ Functions of Tensor Inputs & Outputs
§ Mix and Match with Operations
§ Assumes 1st Dimension is Batch Size
§ Handles One (1) to Many (*) Inputs
§ Special Types of Layers
§ Loss per Mini-Batch
§ Accuracy and MSE Track Across Mini-Batches

69. CANNED ESTIMATORS
§ Commonly-Used Estimators
§ Pre-Tested and Pre-Tuned
§ DNNClassifer, TensorForestEstimator
§ Always Use Canned Estimators If Possible
§ Reduced Lines of Code, Complexity, and Bugs
§ Use FeatureColumns to Define & Create Features
Custom vs. Canned
@ Google, August, 2017

70. FEATURECOLUMN ABSTRACTION
§ Used by Canned Estimator
§ Simplifies Input Ingestion
§ Declarative Way to Specify Model Training Inputs
§ Converts Sparse Features to Dense Tensors
§ Sparse Features: Query Keyword, Url, ProductID,…
§ Wide/Linear Models Use Feature-Crossing
§ Deep Models Use Embeddings

71. SINGLE VS. MULTI-OBJECTIVES + HEADS
§ Single-Objective Estimator
§ Single classification prediction
§ Multi-Objective Estimator
§ Two (2) classification predictions
§ Or One (1) classification prediction + One(1) final layer
§ Multiple Heads Are Used to Ensemble Models
§ Treats neural network as a feature engineering step!

72. EXPERIMENT API
§ Easier-to-Use Distributed TensorFlow
§ Combines Estimator with input_fn()
§ Used for Training, Evaluation, & Hyper-Parameter Tuning
§ Distributed Training Default to Data-Parallel & Async
§ Cluster Configuration is Fixed at Start of Training Job
§ No Auto-Scaling Allowed!!

73. ESTIMATOR & EXPERIMENT CONFIGS
§ TF_CONFIG
§ Special environment variable for config
§ Defines ClusterSpec in JSON incl. master, workers, PS’s
§ Must set ”{environment”:“cloud”} for distributed mode
§ RunConfig: Defines checkpoint interval, output directory, …
§ HParams: Hyper-parameter tuning parameters and ranges
§ learn_runner creates RunConfig before calling run() & tune()
§ schedule is set based on {”task”:{”type”}}
§ Set to train_and_evaluate for local, single-node training
TF_CONFIG=
'{
"environment": "cloud",
"cluster":
{
"master":["worker0:2222”],
"worker":["worker1:2222"],
"ps": ["ps0:2222"]
},
"task": {"type": "ps",
"index": "0"}
}'

74. SEPARATE TRAINING + EVALUATION
§ Separate Training and Evaluation Clusters
§ Evaluate Upon Checkpoint
§ Avoid Resource Contention
§ Let Training Continue in Parallel with Evaluation
Training
Cluster
Evaluation
Cluster
Parameter Server
Cluster

75. LET’S TRAIN DISTRIBUTED TENSORFLOW
§ Navigate to the following notebook:
05_Train_Model_Distributed_CPU
or 05a_Train_Model_Distributed_GPU
§ https://github.com/PipelineAI/pipeline/tree/master/
gpu.ml/notebooks

76. PULSE CHECK

77. BREAK
§ Please 🌟 this GitHub Repo!
§ All slides, code, notebooks, and Docker images here:
https://github.com/PipelineAI/pipeline/tree/master/gpu.ml
Need Help?
Use the Chat!

78. AGENDA
Part 1: Optimize TensorFlow Model Training
§ GPUs and TensorFlow
§ Train, Inspect, and Debug TensorFlow Models
§ TensorFlow Distributed Model Training on a Cluster
§ Optimize Training with JIT XLA Compiler

79. XLA FRAMEWORK
§ Accelerated Linear Algebra (XLA)
§ Goals:
§ Reduce reliance on custom operators
§ Improve execution speed
§ Improve memory usage
§ Reduce mobile footprint
§ Improve portability
§ Helps TF Stay Flexible and Performant

80. XLA HIGH LEVEL OPTIMIZER (HLO)
§ Compiler Intermediate Representation (IR)
§ Independent of source and target language
§ Define Graphs using HLO Language
§ XLA Step 1 Emits Target-Independent HLO
§ XLA Step 2 Emits Target-Dependent LLVM
§ LLVM Emits Native Code Specific to Target
§ Supports x86-64, ARM64 (CPU), and NVPTX (GPU)

81. JIT COMPILER
§ Just-In-Time Compiler
§ Built on XLA Framework
§ Goals:
§ Reduce memory movement – especially useful on GPUs
§ Reduce overhead of multiple function calls
§ Similar to Spark Operator Fusing in Spark 2.0
§ Unroll Loops, Fuse Operators, Fold Constants, …
§ Scope to session, device, or `with jit_scope():`

82. VISUALIZING JIT COMPILER IN ACTION
Before After
Google Web Tracing Framework:
http://google.github.io/tracing-framework/
from tensorflow.python.client import timeline
trace =
timeline.Timeline(step_stats=run_metadata.step_stats)
with open('timeline.json', 'w') as trace_file:
trace_file.write(
trace.generate_chrome_trace_format(show_memory=True))

83. VISUALIZING FUSING OPERATORS
pip install graphviz
dot -Tpng
/tmp/hlo_graph_1.w5LcGs.dot
-o hlo_graph_1.png
GraphViz:
http://www.graphviz.org
hlo_*.dot files generated by XLA

84. LET’S TRAIN WITH XLA CPU
§ Navigate to the following notebook:
06_Train_Model_XLA_CPU
§ https://github.com/PipelineAI/pipeline/tree/master/
gpu.ml/notebooks

85. LET’S TRAIN WITH XLA GPU
§ Navigate to the following notebook:
06a_Train_Model_XLA_GPU
§ https://github.com/PipelineAI/pipeline/tree/master/
gpu.ml/notebooks

86. AGENDA
Part 0: Latest PipelineAI Research
Part 1: Optimize TensorFlow Model Training
Part 2: Optimize TensorFlow Model Serving

87. AGENDA
Part 2: Optimize TensorFlow Model Serving
§ AOT XLA Compiler and Graph Transform Tool
§ Key Components of TensorFlow Serving
§ Deploy Optimized TensorFlow Model
§ Optimize TensorFlow Serving Runtime

88. AOT COMPILER
§ Standalone, Ahead-Of-Time (AOT) Compiler
§ Built on XLA framework
§ tfcompile
§ Creates executable with minimal TensorFlow Runtime needed
§ Includes only dependencies needed by subgraph computation
§ Creates functions with feeds (inputs) and fetches (outputs)
§ Packaged as cc_libary header and object files to link into your app
§ Commonly used for mobile device inference graph
§ Currently, only CPU x86-64 and ARM are supported - no GPU

89. GRAPH TRANSFORM TOOL (GTT)
§ Post-Training Optimization to Prepare for Inference
§ Remove Training-only Ops (checkpoint, drop out, logs)
§ Remove Unreachable Nodes between Given feed -> fetch
§ Fuse Adjacent Operators to Improve Memory Bandwidth
§ Fold Final Batch Norm mean and variance into Variables
§ Round Weights/Variables to improve compression (ie. 70%)
§ Quantize (FP32 -> INT8) to Speed Up Math Operations

90. BEFORE OPTIMIZATIONS

91. GRAPH TRANSFORM TOOL
transform_graph
--in_graph=tensorflow_inception_graph.pb ß Original Graph
--out_graph=optimized_inception_graph.pb ß Transformed Graph
--inputs='Mul' ß Feed (Input)
--outputs='softmax' ß Fetch (Output)
--transforms=' ß List of Transforms
strip_unused_nodes
remove_nodes(op=Identity, op=CheckNumerics)
fold_constants(ignore_errors=true)
fold_batch_norms
fold_old_batch_norms
quantize_weights
quantize_nodes'

92. AFTER STRIPPING UNUSED NODES
§ Optimizations
§ strip_unused_nodes
§ Results
§ Graph much simpler
§ File size much smaller

93. AFTER REMOVING UNUSED NODES
§ Optimizations
§ strip_unused_nodes
§ remove_nodes
§ Results
§ Pesky nodes removed
§ File size a bit smaller

94. AFTER FOLDING CONSTANTS
§ Optimizations
§ strip_unused_nodes
§ remove_nodes
§ fold_constants
§ Results
§ Placeholders (feeds) -> Variables*
(*Why Variables and not Constants?)

95. AFTER FOLDING BATCH NORMS
§ Optimizations
§ strip_unused_nodes
§ remove_nodes
§ fold_constants
§ fold_batch_norms
§ Results
§ Graph remains the same
§ File size approximately the same

96. AFTER QUANTIZING WEIGHTS
§ Optimizations
§ strip_unused_nodes
§ remove_nodes
§ fold_constants
§ fold_batch_norms
§ quantize_weights
§ Results
§ Graph is same, file size is smaller, compute is faster

97. WEIGHT QUANTIZATION
§ FP16 and INT8 Are Smaller and Computationally Simpler
§ Weights/Variables are Constants
§ Easy to Linearly Quantize

98. LET’S OPTIMIZE FOR INFERENCE
§ Navigate to the following notebook:
07_Optimize_Model*
*Why just CPU version? Why not GPU?
§ https://github.com/PipelineAI/pipeline/tree/master/
gpu.ml/notebooks

99. BUT WAIT, THERE’S MORE!

100. ACTIVATION QUANTIZATION
§ Activations Not Known Ahead of Time
§ Depends on input, not easy to quantize
§ Requires Additional Calibration Step
§ Use a “representative” dataset
§ Per Neural Network Layer…
§ Collect histogram of activation values
§ Generate many quantized distributions with different saturation thresholds
§ Choose threshold to minimize…
KL_divergence(ref_distribution, quant_distribution)
§ Not Much Time or Data is Required (Minutes on Commodity Hardware)

101. AFTER ACTIVATION QUANTIZATION
§ Optimizations
§ strip_unused_nodes
§ remove_nodes
§ fold_constants
§ fold_batch_norms
§ quantize_weights
§ quantize_nodes (activations)
§ Results
§ Larger graph, needs calibration!
Requires additional
freeze_requantization_ranges

102. LET’S OPTIMIZE FOR INFERENCE
§ Navigate to the following notebook:
08_Optimize_Model_Activations
§ https://github.com/PipelineAI/pipeline/tree/master/
gpu.ml/notebooks

103. FREEZING MODEL FOR DEPLOYMENT
§ Optimizations
§ strip_unused_nodes
§ remove_nodes
§ fold_constants
§ fold_batch_norms
§ quantize_weights
§ quantize_nodes
§ freeze_graph
§ Results
§ Variables -> Constants
Finally!
We’re Ready to Deploy!!

104. AGENDA
Part 2: Optimize TensorFlow Model Serving
§ AOT XLA Compiler and Graph Transform Tool
§ Key Components of TensorFlow Serving
§ Deploy Optimized TensorFlow Model
§ Optimize TensorFlow Serving Runtime

105. MODEL SERVING TERMINOLOGY
§ Inference
§ Only Forward Propagation through Network
§ Predict, Classify, Regress, …
§ Bundle
§ GraphDef, Variables, Metadata, …
§ Assets
§ ie. Map of ClassificationID -> String
§ {9283: “penguin”, 9284: “bridge”}
§ Version
§ Every Model Has a Version Number (Integer)
§ Version Policy
§ ie. Serve Only Latest (Highest), Serve Both Latest and Previous, …

106. TENSORFLOW SERVING FEATURES
§ Supports Auto-Scaling
§ Custom Loaders beyond File-based
§ Tune for Low-latency or High-throughput
§ Serve Diff Models/Versions in Same Process
§ Customize Models Types beyond HashMap and TensorFlow
§ Customize Version Policies for A/B and Bandit Tests
§ Support Request Draining for Graceful Model Updates
§ Enable Request Batching for Diff Use Cases and HW
§ Supports Optimized Transport with GRPC and Protocol Buffers

107. PREDICTION SERVICE
§ Predict (Original, Generic)
§ Input: List of Tensor
§ Output: List of Tensor
§ Classify
§ Input: List of tf.Example (key, value) pairs
§ Output: List of (class_label: String, score: float)
§ Regress
§ Input: List of tf.Example (key, value) pairs
§ Output: List of (label: String, score: float)

108. PREDICTION INPUTS + OUTPUTS
§ SignatureDef
§ Defines inputs and outputs
§ Maps external (logical) to internal (physical) tensor names
§ Allows internal (physical) tensor names to change
from tensorflow.python.saved_model import utils
from tensorflow.python.saved_model import signature_constants
from tensorflow.python.saved_model import signature_def_utils
graph = tf.get_default_graph()
x_observed = graph.get_tensor_by_name('x_observed:0')
y_pred = graph.get_tensor_by_name('add:0')
inputs_map = {'inputs': x_observed}
outputs_map = {'outputs': y_pred}
predict_signature =
signature_def_utils.predict_signature_def(inputs=inputs_map,
outputs=outputs_map)

109. MULTI-HEADED INFERENCE
§ Inputs Pass Through Model Once
§ Model Returns Multiple Predictions or “Heads” including:
1. Human-readable prediction (ie. “penguin”, “church”,…)
2. Final layer of scores (float vector)
§ Final Layer of floats Pass to the Next Model in Ensemble
§ Optimizes Bandwidth, CPU/GPU, Latency, Memory
§ Enables Complex Model Composing and Ensembling

110. BUILD YOUR OWN MODEL SERVER
§ Adapt GRPC(Google) <-> HTTP (REST of the World)
§ Perform Batch Inference vs. Request/Response
§ Handle Requests Asynchronously
§ Support Mobile, Embedded Inference
§ Customize Request Batching
§ Add Circuit Breakers, Fallbacks
§ Control Latency Requirements
§ Reduce Number of Moving Parts
#include
“tensorflow_serving/model_servers/server_core.h”
class MyTensorFlowModelServer {
ServerCore::Options options;
// set options (model name, path, etc)
std::unique_ptr<ServerCore> core;
TF_CHECK_OK(
ServerCore::Create(std::move(options), &core)
);
}
Compile and Link with
libtensorflow.so

111. NVIDIA TENSOR-RT RUNTIME
§ Post-Training Model Optimizations
§ Similar to TF Graph Transform Tool
§ GPU-Optimized Prediction Runtime
§ Alternative to TensorFlow Serving
§ PipelineAI Supports TensorRT!

112. AGENDA
Part 2: Optimize TensorFlow Model Serving
§ AOT XLA Compiler and Graph Transform Tool
§ Key Components of TensorFlow Serving
§ Deploy Optimized TensorFlow Model
§ Optimize TensorFlow Serving Runtime

113. SAVED MODEL FORMAT
§ Navigate to the following notebook:
09_Deploy_Optimized_Model
§ https://github.com/PipelineAI/pipeline/tree/master/
gpu.ml/notebooks

114. AGENDA
Part 2: Optimize TensorFlow Model Serving
§ AOT XLA Compiler and Graph Transform Tool
§ Key Components of TensorFlow Serving
§ Deploy Optimized TensorFlow Model
§ Optimize TensorFlow Serving Runtime

115. REQUEST BATCH TUNING
§ max_batch_size
§ Enables throughput/latency tradeoff
§ Bounded by RAM
§ batch_timeout_micros
§ Defines batch time window, latency upper-bound
§ Bounded by RAM
§ num_batch_threads
§ Defines parallelism
§ Bounded by CPU cores
§ max_enqueued_batches
§ Defines queue upper bound, throttling
§ Bounded by RAM
Reaching either threshold
will trigger a batch

116. ADVANCED BATCHING & SERVING TIPS
§ Batch Just the GPU/TPU Portions of the Computation Graph
§ Batch Arbitrary Sub-Graphs using Batch / Unbatch Graph Ops
§ Distribute Large Models Into Shards Across TensorFlow Model Servers
§ Batch RNNs Used for Sequential and Time-Series Data
§ Find Best Batching Strategy For Your Data Through Experimentation
§ BasicBatchScheduler: Homogeneous requests (ie Regress or Classify)
§ SharedBatchScheduler: Mixed requests, multi-step, ensemble predict
§ StreamingBatchScheduler: Mixed CPU/GPU/IO-bound Workloads
§ Serve Only One (1) Model Inside One (1) TensorFlow Serving Process
§ Much Easier to Debug, Tune, Scale, and Manage Models in Production.

117. LET’S DEPLOY OPTIMIZED MODEL
§ Navigate to the following notebook:
10_Optimize_Model_Server
§ https://github.com/PipelineAI/pipeline/tree/master/
gpu.ml/notebooks

118. AGENDA
Part 0: Latest PipelineAI Research
Part 1: Optimize TensorFlow Model Training
Part 2: Optimize TensorFlow Model Serving

119. THANK YOU!! QUESTIONS?
§ https://github.com/PipelineAI/pipeline/
§ Please 🌟 this GitHub Repo!
§ All slides, code, notebooks, and Docker images here:
https://github.com/PipelineAI/pipeline/tree/master/gpu.ml
Contact Me
chris@pipeline.ai
@cfregly