llvm/tools/bugpoint/ListReducer.h - toolchain/llvm-project - Gitiles

 //===- ListReducer.h - Trim down list while retaining property --*- C++ -*-===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is distributed under the University of Illinois Open Source
 // License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This class is to be used as a base class for operations that want to zero in
 // on a subset of the input which still causes the bug we are tracking.
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_TOOLS_BUGPOINT_LISTREDUCER_H
 #define LLVM_TOOLS_BUGPOINT_LISTREDUCER_H

 #include "llvm/Support/Error.h"
 #include "llvm/Support/raw_ostream.h"
 #include <algorithm>
 #include <cstdlib>
 #include <random>
 #include <vector>

 namespace llvm {

 extern bool BugpointIsInterrupted;

 template <typename ElTy> struct ListReducer {
   enum TestResult {
     NoFailure,  // No failure of the predicate was detected
     KeepSuffix, // The suffix alone satisfies the predicate
     KeepPrefix  // The prefix alone satisfies the predicate
   };

   virtual ~ListReducer() {}

   /// This virtual function should be overriden by subclasses to implement the
   /// test desired.  The testcase is only required to test to see if the Kept
   /// list still satisfies the property, but if it is going to check the prefix
   /// anyway, it can.
   virtual Expected<TestResult> doTest(std::vector<ElTy> &Prefix,
                                       std::vector<ElTy> &Kept) = 0;

   /// This function attempts to reduce the length of the specified list while
   /// still maintaining the "test" property.  This is the core of the "work"
   /// that bugpoint does.
   Expected<bool> reduceList(std::vector<ElTy> &TheList) {
     std::vector<ElTy> empty;
     std::mt19937 randomness(0x6e5ea738);  // Seed the random number generator
     Expected<TestResult> Result = doTest(TheList, empty);
     if (Error E = Result.takeError())
       return std::move(E);
     switch (*Result) {
     case KeepPrefix:
       if (TheList.size() == 1) // we are done, it's the base case and it fails
         return true;
       else
         break; // there's definitely an error, but we need to narrow it down

     case KeepSuffix:
       // cannot be reached!
       llvm_unreachable("bugpoint ListReducer internal error: "
                        "selected empty set.");

     case NoFailure:
       return false; // there is no failure with the full set of passes/funcs!
     }

     // Maximal number of allowed splitting iterations,
     // before the elements are randomly shuffled.
     const unsigned MaxIterationsWithoutProgress = 3;

     // Maximal number of allowed single-element trim iterations. We add a
     // threshold here as single-element reductions may otherwise take a
     // very long time to complete.
     const unsigned MaxTrimIterationsWithoutBackJump = 3;
     bool ShufflingEnabled = true;

   Backjump:
     unsigned MidTop = TheList.size();
     unsigned MaxIterations = MaxIterationsWithoutProgress;
     unsigned NumOfIterationsWithoutProgress = 0;
     while (MidTop > 1) { // Binary split reduction loop
       // Halt if the user presses ctrl-c.
       if (BugpointIsInterrupted) {
         errs() << "\n\n*** Reduction Interrupted, cleaning up...\n\n";
         return true;
       }

       // If the loop doesn't make satisfying progress, try shuffling.
       // The purpose of shuffling is to avoid the heavy tails of the
       // distribution (improving the speed of convergence).
       if (ShufflingEnabled && NumOfIterationsWithoutProgress > MaxIterations) {
         std::vector<ElTy> ShuffledList(TheList);
         std::shuffle(ShuffledList.begin(), ShuffledList.end(), randomness);
         errs() << "\n\n*** Testing shuffled set...\n\n";
         // Check that random shuffle doesn't lose the bug
         Expected<TestResult> Result = doTest(ShuffledList, empty);
         // TODO: Previously, this error was ignored and we treated it as if
         // shuffling hid the bug. This should really either be consumeError if
         // that behaviour was sensible, or we should propagate the error.
         assert(!Result.takeError() && "Shuffling caused internal error?");

         if (*Result == KeepPrefix) {
           // If the bug is still here, use the shuffled list.
           TheList.swap(ShuffledList);
           MidTop = TheList.size();
           // Must increase the shuffling treshold to avoid the small
           // probability of infinite looping without making progress.
           MaxIterations += 2;
           errs() << "\n\n*** Shuffling does not hide the bug...\n\n";
         } else {
           ShufflingEnabled = false; // Disable shuffling further on
           errs() << "\n\n*** Shuffling hides the bug...\n\n";
         }
         NumOfIterationsWithoutProgress = 0;
       }

       unsigned Mid = MidTop / 2;
       std::vector<ElTy> Prefix(TheList.begin(), TheList.begin() + Mid);
       std::vector<ElTy> Suffix(TheList.begin() + Mid, TheList.end());

       Expected<TestResult> Result = doTest(Prefix, Suffix);
       if (Error E = Result.takeError())
         return std::move(E);
       switch (*Result) {
       case KeepSuffix:
         // The property still holds.  We can just drop the prefix elements, and
         // shorten the list to the "kept" elements.
         TheList.swap(Suffix);
         MidTop = TheList.size();
         // Reset progress treshold and progress counter
         MaxIterations = MaxIterationsWithoutProgress;
         NumOfIterationsWithoutProgress = 0;
         break;
       case KeepPrefix:
         // The predicate still holds, shorten the list to the prefix elements.
         TheList.swap(Prefix);
         MidTop = TheList.size();
         // Reset progress treshold and progress counter
         MaxIterations = MaxIterationsWithoutProgress;
         NumOfIterationsWithoutProgress = 0;
         break;
       case NoFailure:
         // Otherwise the property doesn't hold.  Some of the elements we removed
         // must be necessary to maintain the property.
         MidTop = Mid;
         NumOfIterationsWithoutProgress++;
         break;
       }
     }

     // Probability of backjumping from the trimming loop back to the binary
     // split reduction loop.
     const int BackjumpProbability = 10;

     // Okay, we trimmed as much off the top and the bottom of the list as we
     // could.  If there is more than two elements in the list, try deleting
     // interior elements and testing that.
     //
     if (TheList.size() > 2) {
       bool Changed = true;
       std::vector<ElTy> EmptyList;
       unsigned TrimIterations = 0;
       while (Changed) { // Trimming loop.
         Changed = false;

         // If the binary split reduction loop made an unfortunate sequence of
         // splits, the trimming loop might be left off with a huge number of
         // remaining elements (large search space). Backjumping out of that
         // search space and attempting a different split can significantly
         // improve the convergence speed.
         if (std::rand() % 100 < BackjumpProbability)
           goto Backjump;

         for (unsigned i = 1; i < TheList.size() - 1; ++i) {
           // Check interior elts
           if (BugpointIsInterrupted) {
             errs() << "\n\n*** Reduction Interrupted, cleaning up...\n\n";
             return true;
           }

           std::vector<ElTy> TestList(TheList);
           TestList.erase(TestList.begin() + i);

           Expected<TestResult> Result = doTest(EmptyList, TestList);
           if (Error E = Result.takeError())
             return std::move(E);
           if (*Result == KeepSuffix) {
             // We can trim down the list!
             TheList.swap(TestList);
             --i; // Don't skip an element of the list
             Changed = true;
           }
         }
         if (TrimIterations >= MaxTrimIterationsWithoutBackJump)
           break;
         TrimIterations++;
       }
     }

     return true; // there are some failure and we've narrowed them down
   }
 };

 } // End llvm namespace

 #endif
	//===- ListReducer.h - Trim down list while retaining property --- C++ --===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is distributed under the University of Illinois Open Source
	// License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This class is to be used as a base class for operations that want to zero in
	// on a subset of the input which still causes the bug we are tracking.
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_TOOLS_BUGPOINT_LISTREDUCER_H
	#define LLVM_TOOLS_BUGPOINT_LISTREDUCER_H

	#include "llvm/Support/Error.h"
	#include "llvm/Support/raw_ostream.h"
	#include <algorithm>
	#include <cstdlib>
	#include <random>
	#include <vector>

	namespace llvm {

	extern bool BugpointIsInterrupted;

	template <typename ElTy> struct ListReducer {
	enum TestResult {
	NoFailure, // No failure of the predicate was detected
	KeepSuffix, // The suffix alone satisfies the predicate
	KeepPrefix // The prefix alone satisfies the predicate
	};

	virtual ~ListReducer() {}

	/// This virtual function should be overriden by subclasses to implement the
	/// test desired. The testcase is only required to test to see if the Kept
	/// list still satisfies the property, but if it is going to check the prefix
	/// anyway, it can.
	virtual Expected<TestResult> doTest(std::vector<ElTy> &Prefix,
	std::vector<ElTy> &Kept) = 0;

	/// This function attempts to reduce the length of the specified list while
	/// still maintaining the "test" property. This is the core of the "work"
	/// that bugpoint does.
	Expected<bool> reduceList(std::vector<ElTy> &TheList) {
	std::vector<ElTy> empty;
	std::mt19937 randomness(0x6e5ea738); // Seed the random number generator
	Expected<TestResult> Result = doTest(TheList, empty);
	if (Error E = Result.takeError())
	return std::move(E);
	switch (*Result) {
	case KeepPrefix:
	if (TheList.size() == 1) // we are done, it's the base case and it fails
	return true;
	else
	break; // there's definitely an error, but we need to narrow it down

	case KeepSuffix:
	// cannot be reached!
	llvm_unreachable("bugpoint ListReducer internal error: "
	"selected empty set.");

	case NoFailure:
	return false; // there is no failure with the full set of passes/funcs!
	}

	// Maximal number of allowed splitting iterations,
	// before the elements are randomly shuffled.
	const unsigned MaxIterationsWithoutProgress = 3;

	// Maximal number of allowed single-element trim iterations. We add a
	// threshold here as single-element reductions may otherwise take a
	// very long time to complete.
	const unsigned MaxTrimIterationsWithoutBackJump = 3;
	bool ShufflingEnabled = true;

	Backjump:
	unsigned MidTop = TheList.size();
	unsigned MaxIterations = MaxIterationsWithoutProgress;
	unsigned NumOfIterationsWithoutProgress = 0;
	while (MidTop > 1) { // Binary split reduction loop
	// Halt if the user presses ctrl-c.
	if (BugpointIsInterrupted) {
	errs() << "\n\n*** Reduction Interrupted, cleaning up...\n\n";
	return true;
	}

	// If the loop doesn't make satisfying progress, try shuffling.
	// The purpose of shuffling is to avoid the heavy tails of the
	// distribution (improving the speed of convergence).
	if (ShufflingEnabled && NumOfIterationsWithoutProgress > MaxIterations) {
	std::vector<ElTy> ShuffledList(TheList);
	std::shuffle(ShuffledList.begin(), ShuffledList.end(), randomness);
	errs() << "\n\n*** Testing shuffled set...\n\n";
	// Check that random shuffle doesn't lose the bug
	Expected<TestResult> Result = doTest(ShuffledList, empty);
	// TODO: Previously, this error was ignored and we treated it as if
	// shuffling hid the bug. This should really either be consumeError if
	// that behaviour was sensible, or we should propagate the error.
	assert(!Result.takeError() && "Shuffling caused internal error?");

	if (*Result == KeepPrefix) {
	// If the bug is still here, use the shuffled list.
	TheList.swap(ShuffledList);
	MidTop = TheList.size();
	// Must increase the shuffling treshold to avoid the small
	// probability of infinite looping without making progress.
	MaxIterations += 2;
	errs() << "\n\n*** Shuffling does not hide the bug...\n\n";
	} else {
	ShufflingEnabled = false; // Disable shuffling further on
	errs() << "\n\n*** Shuffling hides the bug...\n\n";
	}
	NumOfIterationsWithoutProgress = 0;
	}

	unsigned Mid = MidTop / 2;
	std::vector<ElTy> Prefix(TheList.begin(), TheList.begin() + Mid);
	std::vector<ElTy> Suffix(TheList.begin() + Mid, TheList.end());

	Expected<TestResult> Result = doTest(Prefix, Suffix);
	if (Error E = Result.takeError())
	return std::move(E);
	switch (*Result) {
	case KeepSuffix:
	// The property still holds. We can just drop the prefix elements, and
	// shorten the list to the "kept" elements.
	TheList.swap(Suffix);
	MidTop = TheList.size();
	// Reset progress treshold and progress counter
	MaxIterations = MaxIterationsWithoutProgress;
	NumOfIterationsWithoutProgress = 0;
	break;
	case KeepPrefix:
	// The predicate still holds, shorten the list to the prefix elements.
	TheList.swap(Prefix);
	MidTop = TheList.size();
	// Reset progress treshold and progress counter
	MaxIterations = MaxIterationsWithoutProgress;
	NumOfIterationsWithoutProgress = 0;
	break;
	case NoFailure:
	// Otherwise the property doesn't hold. Some of the elements we removed
	// must be necessary to maintain the property.
	MidTop = Mid;
	NumOfIterationsWithoutProgress++;
	break;
	}
	}

	// Probability of backjumping from the trimming loop back to the binary
	// split reduction loop.
	const int BackjumpProbability = 10;

	// Okay, we trimmed as much off the top and the bottom of the list as we
	// could. If there is more than two elements in the list, try deleting
	// interior elements and testing that.
	//
	if (TheList.size() > 2) {
	bool Changed = true;
	std::vector<ElTy> EmptyList;
	unsigned TrimIterations = 0;
	while (Changed) { // Trimming loop.
	Changed = false;

	// If the binary split reduction loop made an unfortunate sequence of
	// splits, the trimming loop might be left off with a huge number of
	// remaining elements (large search space). Backjumping out of that
	// search space and attempting a different split can significantly
	// improve the convergence speed.
	if (std::rand() % 100 < BackjumpProbability)
	goto Backjump;

	for (unsigned i = 1; i < TheList.size() - 1; ++i) {
	// Check interior elts
	if (BugpointIsInterrupted) {
	errs() << "\n\n*** Reduction Interrupted, cleaning up...\n\n";
	return true;
	}

	std::vector<ElTy> TestList(TheList);
	TestList.erase(TestList.begin() + i);

	Expected<TestResult> Result = doTest(EmptyList, TestList);
	if (Error E = Result.takeError())
	return std::move(E);
	if (*Result == KeepSuffix) {
	// We can trim down the list!
	TheList.swap(TestList);
	--i; // Don't skip an element of the list
	Changed = true;
	}
	}
	if (TrimIterations >= MaxTrimIterationsWithoutBackJump)
	break;
	TrimIterations++;
	}
	}

	return true; // there are some failure and we've narrowed them down
	}
	};

	} // End llvm namespace

	#endif