//===- llvm/Support/DebugCounter.h - Debug counter support ------*- C++ -*-===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// /// \file /// \brief This file provides an implementation of debug counters. Debug /// counters are a tool that let you narrow down a miscompilation to a specific /// thing happening. /// /// To give a use case: Imagine you have a file, very large, and you /// are trying to understand the minimal transformation that breaks it. Bugpoint /// and bisection is often helpful here in narrowing it down to a specific pass, /// but it's still a very large file, and a very complicated pass to try to /// debug. That is where debug counting steps in. You can instrument the pass /// with a debug counter before it does a certain thing, and depending on the /// counts, it will either execute that thing or not. The debug counter itself /// consists of a skip and a count. Skip is the number of times shouldExecute /// needs to be called before it returns true. Count is the number of times to /// return true once Skip is 0. So a skip=47, count=2 ,would skip the first 47 /// executions by returning false from shouldExecute, then execute twice, and /// then return false again. /// Note that a counter set to a negative number will always execute. /// For a concrete example, during predicateinfo creation, the renaming pass /// replaces each use with a renamed use. //// /// If I use DEBUG_COUNTER to create a counter called "predicateinfo", and /// variable name RenameCounter, and then instrument this renaming with a debug /// counter, like so: /// /// if (!DebugCounter::shouldExecute(RenameCounter) /// <continue or return or whatever not executing looks like> /// /// Now I can, from the command line, make it rename or not rename certain uses /// by setting the skip and count. /// So for example /// bin/opt -debug-counter=predicateinfo-skip=47,predicateinfo-count=1 /// will skip renaming the first 47 uses, then rename one, then skip the rest. //===----------------------------------------------------------------------===// #ifndef LLVM_SUPPORT_DEBUGCOUNTER_H #define LLVM_SUPPORT_DEBUGCOUNTER_H #include "llvm/ADT/DenseMap.h" #include "llvm/ADT/UniqueVector.h" #include "llvm/Support/CommandLine.h" #include "llvm/Support/Debug.h" #include "llvm/Support/raw_ostream.h" #include <string> namespace llvm { class DebugCounter { public: /// \brief Returns a reference to the singleton instance. static DebugCounter &instance(); // Used by the command line option parser to push a new value it parsed. void push_back(const std::string &); // Register a counter with the specified name. // // FIXME: Currently, counter registration is required to happen before command // line option parsing. The main reason to register counters is to produce a // nice list of them on the command line, but i'm not sure this is worth it. static unsigned registerCounter(StringRef Name, StringRef Desc) { return instance().addCounter(Name, Desc); } inline static bool shouldExecute(unsigned CounterName) { // Compile to nothing when debugging is off #ifdef NDEBUG return true; #else auto &Us = instance(); auto Result = Us.Counters.find(CounterName); if (Result != Us.Counters.end()) { auto &CounterPair = Result->second; // We only execute while the skip (first) is zero and the count (second) // is non-zero. // Negative counters always execute. if (CounterPair.first < 0) return true; if (CounterPair.first != 0) { --CounterPair.first; return false; } if (CounterPair.second < 0) return true; if (CounterPair.second != 0) { --CounterPair.second; return true; } return false; } // Didn't find the counter, should we warn? return true; #endif // NDEBUG } // Return true if a given counter had values set (either programatically or on // the command line). This will return true even if those values are // currently in a state where the counter will always execute. static bool isCounterSet(unsigned ID) { return instance().Counters.count(ID); } // Return the skip and count for a counter. This only works for set counters. static std::pair<int, int> getCounterValue(unsigned ID) { auto &Us = instance(); auto Result = Us.Counters.find(ID); assert(Result != Us.Counters.end() && "Asking about a non-set counter"); return Result->second; } // Set a registered counter to a given value. static void setCounterValue(unsigned ID, const std::pair<int, int> &Val) { auto &Us = instance(); Us.Counters[ID] = Val; } // Dump or print the current counter set into llvm::dbgs(). LLVM_DUMP_METHOD void dump() const; void print(raw_ostream &OS) const; // Get the counter ID for a given named counter, or return 0 if none is found. unsigned getCounterId(const std::string &Name) const { return RegisteredCounters.idFor(Name); } // Return the number of registered counters. unsigned int getNumCounters() const { return RegisteredCounters.size(); } // Return the name and description of the counter with the given ID. std::pair<std::string, std::string> getCounterInfo(unsigned ID) const { return std::make_pair(RegisteredCounters[ID], CounterDesc.lookup(ID)); } // Iterate through the registered counters typedef UniqueVector<std::string> CounterVector; CounterVector::const_iterator begin() const { return RegisteredCounters.begin(); } CounterVector::const_iterator end() const { return RegisteredCounters.end(); } private: unsigned addCounter(const std::string &Name, const std::string &Desc) { unsigned Result = RegisteredCounters.insert(Name); CounterDesc[Result] = Desc; return Result; } DenseMap<unsigned, std::pair<long, long>> Counters; DenseMap<unsigned, std::string> CounterDesc; CounterVector RegisteredCounters; }; #define DEBUG_COUNTER(VARNAME, COUNTERNAME, DESC) \ static const unsigned VARNAME = \ DebugCounter::registerCounter(COUNTERNAME, DESC); } // namespace llvm #endif