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Dependence-Based Value Prediction

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Dependence-Based Value Prediction Yiannakis Sazeides University of Cyprus yanos_at_ucy.ac.cy UPC-Barcelona 17/5/2001 – PowerPoint PPT presentation

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Title: Dependence-Based Value Prediction


1
Dependence-Based Value Prediction
  • Yiannakis Sazeides
  • University of Cyprus
  • yanos_at_ucy.ac.cy
  • UPC-Barcelona 17/5/2001

2
Motivation
  • Improve Performance (reduce complexity, save
    power...)
  • What limits performance? Dependences
  • Break dependences Prediction
  • Exploits regularity and/or non-uniformity in
    predicted information

3
Predicted Information
  • Architectural
  • dependences control, address, value, memory
  • Non-Architectural
  • structural constrains cache misses, bank
    conflicts
  • reduce hardware complexity cache sets, shared
    patterns

4
Use of Predicted Information
  • Speculative/Non-Speculative
  • Depends on whether predicted information can
    directly/indirectly cause an incorrect update of
    architected state
  • non-speculative branch prediction for
    instruction prefetching
  • speculative branch prediction for instruction
    execution
  • Hardware/Software

5
Trends
  • Identify and eliminate predictability at
    computational levels below programming
  • Predictors in almost all high performance
    processors and many compilers
  • Technological evolution and limitations will
    increase latency and make predictive techniques
    more important
  • deeper pipelines
  • fast processor/slow memory
  • distributed microarchitectures

6
Our motivation
  • Can value prediction help?
  • How to use value predictability?
  • Wholistic approach all types not just vp and
    coarser grain
  • Absolutely curious to discover, understand and
    use the esoteric program properties causing the
    predictability and non-uniformity observed in
    program information

7
This talk...
  • Hypothesis dependence information influences the
    predictability of program values
  • Propose and evaluate various dependence-based
    value predictors
  • Approach theoretical and practical
  • Work in progress...

8
Outline
  • Introduction
  • Background on value prediction
  • Dependence Info and Predictability
  • Dependence-based Value Predictors
  • Results
  • Future work

9
Value Sequences Produced by Instructions
  • Basic Sequences
  • Constant 0 0 0 0 0
  • Stride 4 3 2 1 0
  • Non-Stride -1 23 10 94
  • Repeating Sequences (composition of basic
    sequences)
  • Repeated Stride 4 3 2 1 0 4 3 2 1 0
  • Repeated Non-Stride -1 23 10 94 -1 23 10 94

10
Local History Value Predictors
  • Computational-Based
  • compute next value by performing a computation on
    previous value(s)
  • Context-Based
  • learn the value that follows a finite number of
    previous values (context) and predict that value
    when context repeats
  • need to observe a context-value before predicting
    correctly
  • Hybrid Delta-Predictor

11
Last Value Predictor
12
Stride Predictor
13
Context-Based Predictor
14
Hybrid Predictor
15
Causes of Predictability
  • Model Based on Dependence Graph
  • Robustness predictability due to program control
    structure and immediate values not input data
  • Predictability generation-propagation termination
  • need to consider info beyond local scope
  • dependence information holds potential to
    increase accuracy of value prediction

16
Hypothesis/Fact
  • The predictability of an instruction is
    determined by the information on the dependence
    path that leads to it
  • Predict the value produced by an instruction
    based on the values and/or information of its
    predecessors

17
Outline
  • Introduction
  • Background on value prediction
  • Dependence Info and Predictability
  • Dependence-based Value Predictors
  • Results
  • Future work

18
Example
19
Observations
  • All instructions can trace dependence back to 6
  • 6 used as an induction variable
  • Use information about 6 to get predictions

20
Example
  • Use value in 6 to predict instruction 7
    Value of 6 Output of Instr. 7
    0,..,13, 15, 31..63 1
    14, 16..30 0
  • Local history with lt47 previous values mispredicts

21
Dependence-Based Prediction
  • Prediction based on information from the
    component of the predicted instruction
    i Output PF(Componenti)
  • Component
  • backward dynamic data dependence slice
  • node info pcs, optypes, immed., outcomes
  • livein values (values not produced by component,
    register and memory)

22
Dependence-Based Prediction
  • In general, use information from components of
    previous instructions Output
    PF(Ci-n..Ci-1,Ci)

23
Perspective
  • Virtually all predictors are functions of
    component approximations to values
  • Practical Limitation predictors can rely on a
    subset of components and information

24
Component Approximation
  • Approximation accuracy depends on information
    used from component
  • What limits approximation accuracy
  • finite resources and aliasing
  • amount of information to be stored
  • how soon a prediction can be made

25
Existing Predictors
  • Interesting with how little information
    predictors work well
  • Global History Branch Predictors
  • use information from multiple previous branch
    components OutputPF(Ci-n..Ci-1,Ci)
  • Note components may be unrelated (longer learning
    and destructive aliasing)

26
Dependence Information
  • A lot of information to choose from
  • Which predecessors
  • recent, recurrent, earliest, all
  • Information
  • values
  • register, memory names
  • pc, optypes, immediates
  • dependence distance
  • Propagation through registers or memory

27
Ideas predict based on
  • Values of recurrent predecessors
  • values indicating location in program

28
Based on Recurrent Predecessors
29
Ideas predict based on
  • Values of recurrent predecessors
  • values indicating location in program
  • no sp
  • sp with last SP value and PC selection of stride

30
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31
Dependence-Based Stack Pointer Predictor
32
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33
Ideas predict based on
  • Values of recurrent predecessors
  • values indicating location in program
  • no sp
  • sp with last SP value and PC selection of stride
  • Distance from predecessors
  • distance indicates coordinates in program
  • predict values not based on values
  • no sp

34
Based on Dependence Distance
35
Ideas predict based on
  • Values of recurrent predecessors
  • values indicating location in program
  • no sp
  • sp with last SP value and PC selection of stride
  • Distance from predecessors
  • distance indicates coordinates in program
  • predict values not based on values
  • no sp
  • Most recently known processor state
  • isolate non-determinism

36
Based on Recent Predecessors
37
Outline
  • Introduction
  • Background on value prediction
  • Dependence Info and Predictability
  • Dependence-based Value Predictors
  • Results
  • Future work

38
Prediction Process
  • To predict an instruction
  • Construction of Dependence Record (DR)
  • approximation of the information on the component
    of the instruction
  • Use DR to obtain a prediction (directly or
    indirectly)

39
DBVP Predictor with CT
40
DBVP Register (DBVP-R)
  • Component subset instructions those fetched but
    have not updated yet the architectural state
  • isolates the non-determinism in execution
  • Information used
  • Generate Registers(GR)livein registers (most
    recently known architected state)
  • Dependence Path Id(DPI)pcs, optypes, immediates
    (info about unknown state)

41
Construction of DR for an instruction (GR)
42
Construction of DR for an instruction
- Many instructions same GRs - Differentiate with
DPI
43
DR Construction
  • Information encoded in instructions
  • May be done incrementally off-line and stored in
    a table where it can be retrieved (imprecise?)
  • No investigation of implementation specifics of
    DR construction
  • Memory instructions propagate the dependence info
    through address operands (can be problematic -
    later)

44
DBVP-R Predictor
History Table indexed with register names
contains architected state
45
DBVP Memory (DBVP-M)
  • DBVP-R ignores memory dependences
  • often no correlation between load address and
    value
  • DBVP-M same as DBVP-R with additional
    functionality and information
  • propagation of DR through memory
  • convert def-store-load-use dependence in a
    component to def-use
  • livein memory locations(generate locations GLs)
  • converts values from memory to liveins

46
DR Propagation Through Memory (spilled variable)
47
Livein Memory Locations
48
Generate Locations (GL) and Memory History
Table(MHT)
  • GL is an index into a table (MHT) with values
    written to memory
  • Store-load dependent pairs are assigned MHT
    location
  • Memory Dependence Prediction mechanisms can
    provide the extra functionality required by DBVP-M

49
DBVP-M Predictor
50
Differences DBVP and CB
  • Information used to access tables and table sizes
  • History table is register indexed (vs PC indexed)
  • smaller
  • may be easier to manage speculative updates
  • -possibly provide predictions later
  • Smaller context is required to capture repeated
    behavior

51
Outline
  • Introduction
  • Background on value prediction
  • Dependence Info and Predictability
  • Dependence-based Value Predictors
  • Results
  • Future work

52
Experimental Framework
  • SPECINT95 Benchmarks
  • Study predictors with simple delay model
  • predict d instructions (or up to first
    misprediction)
  • update
  • d is also maximum component size
  • DPI pc, optypes and immediates

53
DBVP-R DPI Information d1, 64K entry VPT
54
DBVP-R VPT Sized1
55
DBVP-R Sensitivity to Delay64K VPT size
56
Problems with increasing d
  • Capacity instruction in different components
    requires more information to be learned

57
Component Redundancy
58
Problems with increasing d
  • Capacity instruction in different components
    requires more information to be learned
  • Destr. Aliasing multiple instances of same
    instruction same prediction

59
Multiple instances same GR and DPI
60
Problems with increasing d
  • Capacity instruction in different components
    requires more information to be learned
    (destructive aliasing)
  • Destr. Aliasing multiple instances of same
    instruction same prediction
  • Capacity increasing d means more information
    needs to be learned

61
Information to be learned

Two combinations
62
Information to be learned
64 combinations
63
Solutions for increasing d
  • Careful partitioning
  • Transform different structure to same
  • Better DPI
  • position
  • count of outstanding instances of an instruction
  • predict only liveouts
  • Predict based on other information
  • recurrence, dependence distance...

64
DBVP-M MHT Sized1, 64K VPT size
65
DBVP-M Sensitivity to Delay
66
DBVP vs CB
67
Conclusions
  • Dependence-based prediction holds potential to
    improve accuracy
  • Use dependence information for prediction
  • Propagation of dependence information through
    memory useful for increased accuracy

68
Current and Future Work
  • Refinement and evaluation of dependence-based
    prediction methods
  • Evaluation in a processor
  • DR construction
  • Characterize program full components
  • size, uniqueness, correlation to predictability

69
Other Work/Interests
  • Prediction and Speculation
  • Program Behavior
  • Distributed Microarchitectures
  • SMT
  • Benchmark characterization

70
I had a great time - thank you all! Hasta luego
amigas y amigos!
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