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2008 Working Conference on Reverse Engineering Grokking Software Architecture Richard C. Holt Software Architecture Group (SWAG) School of Computer Science, University of Waterloo, Canada Retrospective 1998 2008
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2008 Working Conference on Reverse Engineering Grokking Software Architecture Richard C. Holt Software Architecture Group (SWAG) School of Computer Science, University of Waterloo, Canada
Retrospective 1998 2008 Ten years ago.WCRE most influential paper. “Structural Manipulations of Software Architecture using Tarski Relational Algebra” Today.Retrospective. “Grokking Software Architecture” 17 papers in WCRE
Grokking Software Architecture Grokking Software architecture
Overview of Talk: 4 Parts • Part 1. 1998 paper: Hopes & claims • Part 2. Software Architecture • Part 3. Formalizing Boxology • Part 4. ROP: Relation-Oriented Programming & Grok-Like Languages
Part 1.1998 paper: Hopes & claims • Represent software architecture as a typed graph • Graphs with “colors” of edges & nodes • Manipulate & visualize these architectural graphs • Manipulations can be specified algebraically --- and automatically executed In brief: Formalize architectural diagrams and reap the benefits arising from the corresponding mathematics.
CS 746G Topics in Software ArchitectureUniversity of Waterloo • CS746 in Winter 1998 Linux (Operating System) • CS746 in Winter 1999 Apache (Web Server) • CS746 in Winter 2000 Mozilla (Web Browser) • CS746 in Winter 2001 Eazel Nautilus (File Manager) • CS798 in Winter 2002 Postgres et al (Data Base) • CS746 in Winter 2003 EMACS et al (Editor) • CS746 in Winter 2004 Gnumeric (Spreadsheet) • CS746 in Fall 2004 Mozilla (Web Browser -- again) • CS746 in Fall 2005 Open Office (Open Source Office Suite) • CS746 in Fall 2006 Asterisk (Open Phone Switch) • CS746 in Fall 2008 MySQL
Process of View Creation Source code Clustering Parser Facts extracted from code Hierarchic decomposition Grok: Fact manipulator Architectural diagram Layouter Browser
T a c d S e V b f g h Transformations to do Hiding Graph G d T e a V f b Graph I = hideExt(G, S) Graph H = hide(hide(G,T),V)
Lifting Calls Up to File Level call is a procedure call fileCall is a file level call File File fileCall main.c start.h funcDef funcDcl main startup call Procedure body Procedure header fileCall := funcDef o call o inv funcDcl
Part 2.Software Architecture: Boxology Approach • Software architecture: • What is it? • State of practice • How is it represented • Keep It simple • Models & tools • Views of architecture • Extracting As-Built architecture
Software Architecture:What is it? • Confusion. I have a sneaking suspicion that ‘architecture’ is one of the most overused and least understood terms in professional software development circles.Gorton • Consensus. Architecture captures system structure in terms of components [parts] and how they interact.Gorton
Software Architecture: State of the Practice • “It’s common for there to be little or no documentation covering the architecture in many projects.”Gorton • “I'm hopeless when it comes to documentation.”Torvalds • “The architecture that actually predominates in practice is the ‘big ball of mud’ ” Foote et al
Software as Spaghetti Foote et al
Software Architecture: How is it Represented in Practice? • …predominant tools used for architecture documentation are Microsoft Word, Visio and Power PointGorton • What’s needed: Concepts, notations and tools that are • easy to use and • help us produce useful, understandable documentation
KISS: Keep it Simple Stupid “Any fool can make things bigger, more complex, and more violent. It takes a touch of genius - and a lot of courage - to move in the opposite direction.”Einstein “Make everything as simple as possible, but not simpler.”Einstein
Models and Tools for Software Architecture • “UML has, for better or (many would say) worse, become the industry standard ADL [Architecture Design Language]”Shaw • UML “lacks, however, a robust suite of tools for analysis, consistency checking”Shaw
Views of Software Architecture Kruchten End user Users’ View As-Built View Programmers & software managers Scenarios Concurrency View Deployment View System Engineer Integrator
Extracting the As-Built Architecture from the Code • “Reverse engineering is the process of analyzing a subject system to create representations of the system at a higher level of abstraction.”Chikofsky • Relational approach. • Parse the code to produce relations, e.g • (call, P, Q) means proc P calls Q • Manipulate edges into as-built architecture
Boxology as a Central ADL (Architectural Design Language) • “The most widely used design notation [for software architecture] is informal ‘block and arrow’ diagrams.”Gorton
Cross Fertilization!! Rev Eng, S/W Arch, Relational Approach • Reverse engineering • Architecture extraction • As-Built view: Code is king • Traceability • Software architecture • Need for representation & tools • Simplicity & utility • Relational approach • Boxology • Formalization --- Tarski algebra
Part 3. Formalizing Boxology • Boxology is the “Representation of an organized structure as a graph of labeled nodes (‘boxes’) and connections between them (as lines or arrows).”Wikipedia • “Toward boxology: preliminary classification of architectural styles”Shaw
Example Typed Graph r r C C a I b a b I z w E U C C C E C C U x y v v w x y z U U • C = { (r,a), (r,b), (a,v), (a,w) (a,x), (b,y), (b,z) } • I = { (a,b) } • E = { (b,y) } • U = { (v,w), (x,y) }
Boxology is Just Scribbling? • Box & arrow diagrams • Are just scribbles? No • Formalized by typed graphs • Visualized as (nested) boxes & arrows • Manipulated by Tarski algebra etc. • Exchanged as • Triples (RSF), extended to TA, or GXL or …
Boxology has Semantics? Yes • Compare to BNF • Semantics by informal attachment to productions • Compare to Codd’s relational approach • Semantics by interpretation of tables. • Semantics by attributes & descriptions • Separation of concerns • Structure then semantics • Use box/arrow diagrams as underlying formalism for software architecture (Mini-MOF?)
Adding Algebra to Boxology • Tables then Codd relational algebra • N-ary relations • Boxes/arrows then Tarski relational algebra • Binary relations
Example Typed Graph r r C C a I b a b I z w E U C C C E C C U x y v v w x y z U U • C = { (r,a), (r,b), (a,v), (a,w) (a,x), (b,y), (b,z) } • I = { (a,b) } • E = { (b,y) } • U = { (v,w), (x,y) }
Tarski Algebraic Operators Union I + E = {(a,b), (b,y)} Intersection E ^ C = {(b,y)} Difference C - E = {(r,a), (r,b), (a,v), (a,w), (a,x), (b,z)} Inverse inv E = {(y,b)} Composition I o E = {(a,y)} Identity id = {(r,r), (a, a), (b,b), (w,w) … } Transitive Cl. C+ = {(r,a), (r, b), (r,v), (r,w), (r,x), (r,y), (r,z), (a,v), (a,w), (a,x), (b,y), (b,z)} Reflex. T.C. C* = ID + C+
TA Schemas for Box and Arrow Diagrams ref proc var • A Schema in TA • Determines • Types of boxes • Types of edges • Allowed connectivity between edges • Supports inheritance in schemas • Also attributes (strings) on boxes & on edges call instance instance instance instance p q x y call ref Malton WCRE 2005
Why Formalize Boxology??Cause it Makes Our Life Better • Clear understanding & clear specification • What does RSF meaning? • Meaning is independent of implementation • Clarifies deeper concepts, e.g., expressiveness • Generality • Progress in reverse engineering • Progress in software architecture • Not just scribbling
Part 4.ROP: Relation-Oriented Programming & Grok-Like Languages • A paradigm shift
Example: Mickey Eats Swiss Cheese The “eat” relation • Mickey . eat • Swiss • Roquefort • eat . Mickey • Garfield • Fluffy • eat o eat • (Garfield Swiss) • (Garfield Roquefort) • (Fluffy Swiss) • (Fluffy Roquefort) • eat+ • ,,, Garfield Fluffy Mickey Nancy Swiss Roquefort
Example ROP/Grok Program:Is relation R a tree? How you would program this test …
Grok Program: Is R a Tree? Pseudo code if R has no loops & R has one root & R has only single parents then put “R is a tree” Assume each node is a source or target of the contain C relation
Grok Program: Is R a Tree? Pseudo code Grok code if # ( R+^ ID ) = 0 if R has no loops Does transitive closure of R have any self-loops? Yes R R R R a d b c
Grok Program: Is R a Tree? Pseudo code Grok code if # ( R+ ^ ID ) = 0 & # (dom R - rng R) = 1 if R has no loops & R has one root Does R have exactly one source? Yes a dom b c f g d e rng
Grok Program: Is R a Tree? Pseudo code Grok code if # ( R+ ^ ID ) = 0 & # (dom R - rng R) = 1 & # ((R o inv R) - ID) != 0 if R has no loops & R has one root & R has only single parents R o inv R b d inv R Does my child have another parent? Yes R a c
Grok Program: Is R a Tree? Pseudo code Grok code if # ( R+ ^ ID ) = 0 & # (dom R - rng R) = 1 & # ((R o inv R) - ID) != 0 then put “R is a tree” if R has no loops & R has one root & R has only single parents then put “R is a tree” Moral: Relational progamming is not like low level (Java level) programming. Loops typically disappear.
Notation: Does it Matter? By relieving the brain of all unnecessary work, a good notation sets it free to concentrate on more advanced problems, and, in effect, increases the mental power of the race. Alfred North Whitehead
Wins & Losses Using Tarski Algebra • Wins • Good for computing new edges, for finding properties of edges, eg, nodes in loops, leaves, etc. • Losses • Not good for locating patterns involving several nodes, e.g., find complete connected sub-graphs
Notation: Grok (Tarski) vs. Crocopat My parent’s (P) children (C) are my (reflexive) siblings (S) y P C C P x z S S S := P o C S(x,z) := EX(y, P(x,y) & C(y,z)) Grok Crocopat Should Crocopat add Tarski operators??
Characterizing Grok-Like Languages • Relational • Useful for software analysis • Expressiveness • How powerful can a query be? • Codd algebra and Crocopat are more powerful. • How well can a query meet our needs? How writeable? How readable? • Performance of implementation • Can hold large graphs? • Fast enough to manipulate large graphs?
Performance of Grok-Like Languages • Size & speed: OK for --- Grok & Crocopat • All memory resident, no disk access • Hundreds of thousands of edges • Modeling million-line systems • Most operations not more than a few seconds • Crocopat scales up a bit more for transitive closure • House keeping, e.g., time to read files, is critical • Need to test on 64-bit implementations
Data Structures for Binary Relations • Tables: One for each type of relation DBMS • Single table of triples Grok • Linked lists • Pointers and nodes Lsedit, JGrok (caches sorted lists) • BDD: Binary Decision Diagram Relview, Crocopat • Memory efficient storage of binary relations • Works well with dense graphs • Proven useful RelView, Crocopat • Surprising (to me): BDD efficient for transitive closure
Grok-Like Languages Discussion of Grok-Like Languages PS: Paul Klint’s relational language ...
Progress: Using Grok-Like Languages • Enforce architecture rules. Holt 96, Feijs 98, Knodel 08 • Lift dependency edges. Holt 98, Feijs1998 • Find design pattern instances. Consens 98, Beyer 02 • Find violations of patterns. Guo 99 • Find anti-patterns. vanEmden 02, Feijs 98 • Change impact analysis. Feijs 98 • Specify extraction from syntax. Lin 08 • Find source of dependency. Fahmy 01, Feijs 98 • Locate uses of protocols. Wu 01 • Type inference using transitive closure. vanDeursen 99
Conclusions Grokking Software Architecture
Conclusions • Typed graphs nicely formalize various software structures • Software architecture can benefit from a ROP approach • Tarski algebra, added to boxology, is elegant • Does not handle multi-node patterns • Grok-like (ROP) languages are elegant and sufficiently efficient • ROP is high level, is faster, more reliable, more flexible • Lots of • Work done so far • Room for more work