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Reviewers: hans, Jim Reviewed By: Jim Subscribers: jvesely, nhaehnle, mgorny, arphaman, bmahjour, kerbowa, llvm-commits Tags: #llvm Differential Revision: https://reviews.llvm.org/D73017
141 lines
6.5 KiB
ReStructuredText
141 lines
6.5 KiB
ReStructuredText
=========================
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Dependence Graphs in LLVM
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=========================
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.. contents::
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:local:
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Introduction
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============
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Dependence graphs are useful tools in compilers for analyzing relationships
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between various program elements to help guide optimizations. The ideas
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behind these graphs are described in papers [1]_ and [2]_.
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The implementation of these ideas in LLVM may be slightly different than
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what is mentioned in the papers. These differences are documented in
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the `implementation details <implementation-details_>`_.
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.. _DataDependenceGraph:
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Data Dependence Graph
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=====================
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In its simplest form the Data Dependence Graph (or DDG) represents data
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dependencies between individual instructions. Each node in such a graph
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represents a single instruction and is referred to as an "atomic" node.
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It is also possible to combine some atomic nodes that have a simple
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def-use dependency between them into larger nodes that contain multiple-
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instructions.
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As described in [1]_ the DDG uses graph abstraction to group nodes
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that are part of a strongly connected component of the graph
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into special nodes called pi-blocks. pi-blocks represent cycles of data
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dependency that prevent reordering transformations. Since any strongly
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connected component of the graph is a maximal subgraph of all the nodes
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that form a cycle, pi-blocks are at most one level deep. In other words,
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no pi-blocks are nested inside another pi-block, resulting in a
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hierarchical representation that is at most one level deep.
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For example, consider the following:
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.. code-block:: c++
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for (int i = 1; i < n; i++) {
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b[i] = c[i] + b[i-1];
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}
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This code contains a statement that has a loop carried dependence on
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itself creating a cycle in the DDG. The figure bellow illustrates
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how the cycle of dependency is carried through multiple def-use relations
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and a memory access dependency.
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.. image:: cycle.png
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The DDG corresponding to this example would have a pi-block that contains
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all the nodes participating in the cycle, as shown bellow:
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.. image:: cycle_pi.png
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Program Dependence Graph
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========================
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The Program Dependence Graph (or PDG) has a similar structure as the
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DDG, but it is capable of representing both data dependencies and
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control-flow dependencies between program elements such as
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instructions, groups of instructions, basic blocks or groups of
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basic blocks.
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High-Level Design
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=================
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The DDG and the PDG are both directed graphs and they extend the
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``DirectedGraph`` class. Each implementation extends its corresponding
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node and edge types resulting in the inheritance relationship depicted
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in the UML diagram bellow:
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.. image:: uml_nodes_and_edges.png
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Graph Construction
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------------------
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The graph build algorithm considers dependencies between elements of
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a given set of instructions or basic blocks. Any dependencies coming
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into or going out of instructions that do not belong to that range
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are ignored. The steps in the build algorithm for the DDG are very
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similar to the steps in the build algorithm for the PDG. As such,
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one of the design goals is to reuse the build algorithm code to
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allow creation of both DDG and PDG representations while allowing
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the two implementations to define their own distinct and independent
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node and edge types. This is achieved by using the well-known builder
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design pattern to isolate the construction of the dependence graph
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from its concrete representation.
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The following UML diagram depicts the overall structure of the design
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pattern as it applies to the dependence graph implementation.
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.. image:: uml_builder_pattern.png
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Notice that the common code for building the two types of graphs are
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provided in the ``DependenceGraphBuilder`` class, while the ``DDGBuilder``
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and ``PDGBuilder`` control some aspects of how the graph is constructed
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by the way of overriding virtual methods defined in ``DependenceGraphBuilder``.
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Note also that the steps and the names used in this diagram are for
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illustrative purposes and may be different from those in the actual
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implementation.
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Design Trade-offs
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-----------------
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Advantages:
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^^^^^^^^^^^
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- Builder allows graph construction code to be reused for DDG and PDG.
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- Builder allows us to create DDG and PDG as separate graphs.
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- DDG nodes and edges are completely disjoint from PDG nodes and edges allowing them to change easily and independently.
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Disadvantages:
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^^^^^^^^^^^^^^
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- Builder may be perceived as over-engineering at first.
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- There are some similarities between DDG nodes and edges compared to PDG nodes and edges, but there is little reuse of the class definitions.
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- This is tolerable given that the node and edge types are fairly simple and there is little code reuse opportunity anyway.
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.. _implementation-details:
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Implementation Details
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======================
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The current implementation of DDG differs slightly from the dependence
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graph described in [1]_ in the following ways:
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1. The graph nodes in the paper represent three main program components, namely *assignment statements*, *for loop headers* and *while loop headers*. In this implementation, DDG nodes naturally represent LLVM IR instructions. An assignment statement in this implementation typically involves a node representing the ``store`` instruction along with a number of individual nodes computing the right-hand-side of the assignment that connect to the ``store`` node via a def-use edge. The loop header instructions are not represented as special nodes in this implementation because they have limited uses and can be easily identified, for example, through ``LoopAnalysis``.
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2. The paper describes five types of dependency edges between nodes namely *loop dependency*, *flow-*, *anti-*, *output-*, and *input-* dependencies. In this implementation *memory* edges represent the *flow-*, *anti-*, *output-*, and *input-* dependencies. However, *loop dependencies* are not made explicit, because they mainly represent association between a loop structure and the program elements inside the loop and this association is fairly obvious in LLVM IR itself.
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3. The paper describes two types of pi-blocks; *recurrences* whose bodies are SCCs and *IN* nodes whose bodies are not part of any SCC. In this implementation, pi-blocks are only created for *recurrences*. *IN* nodes remain as simple DDG nodes in the graph.
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References
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----------
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.. [1] "D. J. Kuck, R. H. Kuhn, D. A. Padua, B. Leasure, and M. Wolfe (1981). DEPENDENCE GRAPHS AND COMPILER OPTIMIZATIONS."
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.. [2] "J. FERRANTE (IBM), K. J. OTTENSTEIN (Michigan Technological University) and JOE D. WARREN (Rice University), 1987. The Program Dependence Graph and Its Use in Optimization."
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