/** Performs peephole optimizations on a program's live methods. */ private static void peephole(final BloatContext context) { final Set liveMethods = new TreeSet(new MemberRefComparator()); final CallGraph cg = context.getCallGraph(); liveMethods.addAll(cg.liveMethods()); // Perform peephole optimizations. We do this separately because // some peephole optimizations do things to the stack that // inlining doesn't like. For instance, a peephole optimizations // might make it so that a method has a non-empty stack upon // return. Inlining will barf at the sight of this. BloatBenchmark.tr("Performing peephole optimizations"); final Iterator iter = liveMethods.iterator(); while (BloatBenchmark.PEEPHOLE && iter.hasNext()) { try { final MethodEditor live = context.editMethod((MemberRef) iter.next()); Peephole.transform(live); context.commit(live.methodInfo()); context.release(live.methodInfo()); } catch (final NoSuchMethodException ex314) { BloatBenchmark.err.println("** Could not find method " + ex314.getMessage()); ex314.printStackTrace(System.err); System.exit(1); } } }
/** Inlines calls to static methods in the live methods of a given program. */ private static void inline(final BloatContext context) { final Set liveMethods = new TreeSet(new MemberRefComparator()); final CallGraph cg = context.getCallGraph(); liveMethods.addAll(cg.liveMethods()); BloatBenchmark.tr("Inlining " + liveMethods.size() + " live methods"); if (BloatBenchmark.CALLEE_SIZE != -1) { Inline.CALLEE_SIZE = BloatBenchmark.CALLEE_SIZE; } final Iterator iter = liveMethods.iterator(); for (int count = 0; BloatBenchmark.INLINE && iter.hasNext(); count++) { try { final MethodEditor live = context.editMethod((MemberRef) iter.next()); if (context.ignoreMethod(live.memberRef())) { // Don't display ignored methods, it's misleading. continue; } BloatBenchmark.tr( " " + count + ") " + live.declaringClass().name() + "." + live.name() + live.type()); final Inline inline = new Inline(context, BloatBenchmark.SIZE); inline.setMaxCallDepth(BloatBenchmark.DEPTH); inline.inline(live); // Commit here in an attempt to conserve memory context.commit(live.methodInfo()); context.release(live.methodInfo()); } catch (final NoSuchMethodException ex3) { BloatBenchmark.err.println("** Could not find method " + ex3.getMessage()); System.exit(1); } } }
/** Runs BLOAT on a method. */ public static void bloatMethod(final MethodEditor m, final BloatContext context) { try { if (Main.COMPACT_ARRAY_INIT) { // Compact the initialization of arrays of the basic types by // putting the values of the array into a string in the constant // pool. The initialization code is replaced with a loop that // loads the array from the string in the constant pool. if (Main.TRACE) { System.out.println(" Compacting Arrays: " + Main.dateFormat.format(new Date())); } CompactArrayInitializer.transform(m); if (Main.DEBUG) { System.out.println("---------- After compaction:"); m.print(System.out); System.out.println("---------- end print"); } } FlowGraph cfg; // The control flow graph for a method if (Main.TRACE) { System.out.println(" Constructing CFG: " + Main.dateFormat.format(new Date())); } try { // Construct the control flow graph for method m cfg = new FlowGraph(m); } catch (final ClassFormatException ex) { System.err.println(ex.getMessage()); context.release(m.methodInfo()); return; } // We separate out initialization since before this the FlowGraph // more exactly represents the input program. cfg.initialize(); if (Main.TRACE) { System.out.println(" Transforming to SSA: " + Main.dateFormat.format(new Date())); } SSA.transform(cfg); if (FlowGraph.DEBUG) { System.out.println("---------- After SSA:"); cfg.print(System.out); System.out.println("---------- end print"); } if (Main.DEBUG) { cfg.visit(new VerifyCFG(false)); } if (!Tree.USE_STACK) { // Do copy propagation and value numbering first to get rid of // all the extra copies inserted for dups. If they're left in, // it really slows down value numbering. if (Main.PROP) { if (Main.DEBUG) { System.out.println("-----Before Copy Propagation-----"); } if (Main.TRACE) { System.out.println(" Copy propagation: " + Main.dateFormat.format(new Date())); } final ExprPropagation copy = new ExprPropagation(cfg); copy.transform(); if (Main.DEBUG) { cfg.visit(new VerifyCFG(false)); } if (Main.DEBUG) { System.out.println("------After Copy Propagation-----"); cfg.print(System.out); } } } DeadCodeElimination dce = null; if (Main.DCE) { if (Main.TRACE) { System.out.println(" Dead Code Elimination: " + Main.dateFormat.format(new Date())); } if (Main.DEBUG) { System.out.println("---Before Dead Code Elimination--"); } dce = new DeadCodeElimination(cfg); dce.transform(); if (Main.DEBUG) { cfg.visit(new VerifyCFG(false)); } if (Main.DEBUG) { System.out.println("---After Dead Code Elimination---"); cfg.print(System.out); } } if (Main.INFER) { if (Main.DEBUG) { System.out.println("---------Doing type inference--------"); } if (Main.TRACE) { System.out.println(" Type Inferencing: " + Main.dateFormat.format(new Date())); } TypeInference.transform(cfg, context.getHierarchy()); } if (Main.NUMBER) { if (Main.TRACE) { System.out.println(" Value Numbering: " + Main.dateFormat.format(new Date())); } if (Main.DEBUG) { System.out.println("--------Doing value numbering--------"); } (new ValueNumbering()).transform(cfg); } if (Main.FOLD) { if (Main.DEBUG) { System.out.println("--------Before Value Folding---------"); } if (Main.TRACE) { System.out.println(" Value Folding: " + Main.dateFormat.format(new Date())); } (new ValueFolding()).transform(cfg); if (Main.DEBUG) { cfg.visit(new VerifyCFG()); } if (Main.DEBUG) { System.out.println("---------After Value Folding---------"); cfg.print(System.out); } } if (Main.PRE) { if (Main.DEBUG) { System.out.println("-------------Before SSAPRE-----------"); } if (Main.TRACE) { System.out.println(" SSAPRE: " + Main.dateFormat.format(new Date())); } final SSAPRE pre = new SSAPRE(cfg, context); pre.transform(); if (Main.DEBUG) { cfg.visit(new VerifyCFG()); } if (Main.DEBUG) { System.out.println("-------------After SSAPRE------------"); cfg.print(System.out); } } if (Main.FOLD) { if (Main.DEBUG) { System.out.println("--------Before Value Folding---------"); } if (Main.TRACE) { System.out.println(" Value Folding: " + Main.dateFormat.format(new Date())); } (new ValueFolding()).transform(cfg); if (Main.DEBUG) { cfg.visit(new VerifyCFG()); } if (Main.DEBUG) { System.out.println("---------After Value Folding---------"); cfg.print(System.out); } } if (Main.PROP) { if (Main.DEBUG) { System.out.println("-------Before Copy Propagation-------"); } if (Main.TRACE) { System.out.println(" Copy Propagation " + Main.dateFormat.format(new Date())); } final ExprPropagation copy = new ExprPropagation(cfg); copy.transform(); if (Main.DEBUG) { cfg.visit(new VerifyCFG()); } if (Main.DEBUG) { System.out.println("--------After Copy Propagation-------"); cfg.print(System.out); } } // make sure we've done at least one thing since the last DCE if (Main.DCE && (Main.INFER || Main.NUMBER || Main.FOLD || Main.PRE || Main.PROP)) { if (Main.DEBUG) { System.out.println("-----Before Dead Code Elimination----"); } if (Main.TRACE) { System.out.println(" Dead Code Elimination: " + Main.dateFormat.format(new Date())); } dce = new DeadCodeElimination(cfg); dce.transform(); if (Main.DEBUG) { cfg.visit(new VerifyCFG()); } if (Main.DEBUG) { System.out.println("-----After Dead Code Elimination-----"); cfg.print(System.out); } } if (Main.PERSIST) { (new PersistentCheckElimination()).transform(cfg); } if (Main.DIVA) { if (Main.DEBUG) { System.out.println("-----Before DIVA------"); } if (Main.TRACE) { System.out.println(" DIVA: " + Main.dateFormat.format(new Date())); } (new InductionVarAnalyzer()).transform(cfg); if (Main.DEBUG) { System.out.println("-----After DIVA-----"); cfg.print(System.out); } } /* * if (STACK_ALLOC) { if (DEBUG) { * System.out.println("------------Before StackPRE----------"); } * * StackPRE pre = new StackPRE(cfg); pre.transform(); * * if (DEBUG) { cfg.visit(new VerifyCFG()); } * * if (DEBUG) { System.out.println("------------After * StackPRE-----------"); cfg.print(System.out); } } */ // Do the new stack optimization if (Main.OPT_STACK_2) { if (Main.TRACE) { System.out.println(" New stack optimization: " + Main.dateFormat.format(new Date())); } // generate code without doing liveness or register allocation final CodeGenerator codegen = new CodeGenerator(m); codegen.replacePhis(cfg); m.clearCode2(); cfg.visit(codegen); // do stack optimization on the bytecode final StackOpt so = new StackOpt(); so.transform(m); // convert it back to a cfg cfg = new FlowGraph(m); cfg.initialize(); // convert it back to SSA SSA.transform(cfg); // do more dead code elimination (eliminate stores) dce = new DeadCodeElimination(cfg); dce.transform(); } if (Main.TRACE) { System.out.println(" Register allocation: " + Main.dateFormat.format(new Date())); } if (Main.VERIFY) { try { cfg.visit(new VerifyCFG()); } catch (final IllegalArgumentException ee) { System.out.println( " NOTE: CFG did not verify while " + "bloating " + m.name() + " after all optimizations. Exception: " + ee); } } // We're all done performing optimizations. Let's generate some code // and go home. // Perform liveness analysis of variables in the method. // Assign local variables ("registers") to expression values. final Liveness liveness = new Liveness(cfg); final RegisterAllocator alloc = new RegisterAllocator(cfg, liveness); // Gather information which can be used to optimize use of the stack if (CodeGenerator.OPT_STACK) { if (Main.TRACE) { System.out.println(" Old stack optimization: " + Main.dateFormat.format(new Date())); } StackOptimizer.optimizeCFG(cfg); } if (Main.TRACE) { System.out.println(" Code Generation: " + Main.dateFormat.format(new Date())); } // Start the code generation process. final CodeGenerator codegen = new CodeGenerator(m); codegen.replacePhis(cfg); if (Main.DEBUG) { System.out.println("After fixing Phis------------------------"); cfg.print(System.out); System.out.println("End print--------------------------------"); } codegen.simplifyControlFlow(cfg); codegen.allocReturnAddresses(cfg, alloc); if (Main.DEBUG) { System.out.println("After removing empty blocks--------------"); cfg.print(System.out); System.out.println("End print--------------------------------"); } // Clear the old contents of the bytecode store and generate new // code. // Code is generated using a visitor pattern on the CFG. m.clearCode(); cfg.visit(codegen); Peephole.transform(m); // Commit any changes that have been made to the method context.commit(m.methodInfo()); } catch (final Exception ex99) { final String msg = "** Exception while optimizing " + m.name() + m.type() + " of class " + m.declaringClass().name(); System.err.println(msg); System.err.println(ex99.getMessage()); ex99.printStackTrace(System.err); System.exit(1); } }
/** * Performs intraprocedural BLOAT on a program's live methods. * * @param liveMethods Should be alphabetized. This way we can commit a class once we've BLOATed * all of its methods. */ private static void intraBloat(final Collection liveMethods, final BloatContext context) { ClassEditor prevClass = null; final Iterator iter = liveMethods.iterator(); for (int count = 0; iter.hasNext(); count++) { MethodEditor live = null; ClassEditor ce = null; // Hack to make sure commit happens try { live = context.editMethod((MemberRef) iter.next()); ce = context.editClass(live.declaringClass().classInfo()); } catch (final NoSuchMethodException ex3) { BloatBenchmark.err.println("** Could not find method " + ex3.getMessage()); System.exit(1); } /* So we can skip classes or packages */ final String name = ce.type().className(); final String qual = ce.type().qualifier() + "/*"; boolean skip = false; for (int i = 0; i < BloatBenchmark.SKIP.size(); i++) { final String pkg = (String) BloatBenchmark.SKIP.get(i); if (name.equals(pkg) || qual.equals(pkg)) { skip = true; break; } } if (context.ignoreMethod(live.memberRef()) || skip) { // Don't display ignored methods, it's misleading. context.release(live.methodInfo()); continue; } final Runtime runtime = Runtime.getRuntime(); runtime.gc(); final Date start = new Date(); BloatBenchmark.tr( " " + count + ") " + live.declaringClass().name() + "." + live.name() + live.type()); BloatBenchmark.tr(" Start: " + start); try { EDU.purdue.cs.bloat.optimize.Main.TRACE = BloatBenchmark.TRACE; if (!BloatBenchmark.VERIFY) { EDU.purdue.cs.bloat.optimize.Main.VERIFY = false; } EDU.purdue.cs.bloat.optimize.Main.bloatMethod(live, context); } catch (final Exception oops) { BloatBenchmark.err.println("******************************************"); BloatBenchmark.err.println( "Exception while BLOATing " + live.declaringClass().name() + "." + live.name() + live.type()); BloatBenchmark.err.println(oops.getMessage()); oops.printStackTrace(System.err); BloatBenchmark.err.println("******************************************"); } // Commit here in an attempt to conserve memory context.commit(live.methodInfo()); context.release(live.methodInfo()); if (prevClass == null) { prevClass = ce; } else if (!prevClass.equals(ce)) { // We've finished BLOATed the methods for prevClass, commit // prevClass and move on BloatBenchmark.tr(prevClass.type() + " != " + ce.type()); context.commit(prevClass.classInfo()); context.release(prevClass.classInfo()); // context.commitDirty(); // tr(context.toString()); prevClass = ce; } else { context.release(ce.classInfo()); } final Date end = new Date(); BloatBenchmark.tr(" Ellapsed time: " + (end.getTime() - start.getTime()) + " ms"); } context.commitDirty(); }