//===- ProfileInfoLoad.cpp - Load profile information from disk -----------===// // // The LLVM Compiler Infrastructure // // This file is distributed under the University of Illinois Open Source // License. See LICENSE.TXT for details. // //===----------------------------------------------------------------------===// // // The ProfileInfoLoader class is used to load and represent profiling // information read in from the dump file. // //===----------------------------------------------------------------------===// #include "llvm/Analysis/ProfileInfoLoader.h" #include "llvm/Analysis/ProfileInfoTypes.h" #include "llvm/Module.h" #include "llvm/InstrTypes.h" #include "llvm/Support/raw_ostream.h" #include #include #include using namespace llvm; // ByteSwap - Byteswap 'Var' if 'Really' is true. // static inline unsigned ByteSwap(unsigned Var, bool Really) { if (!Really) return Var; return ((Var & (255U<< 0U)) << 24U) | ((Var & (255U<< 8U)) << 8U) | ((Var & (255U<<16U)) >> 8U) | ((Var & (255U<<24U)) >> 24U); } static unsigned AddCounts(unsigned A, unsigned B) { // If either value is undefined, use the other. if (A == ~0U) return B; if (B == ~0U) return A; return A + B; } static void ReadProfilingBlock(const char *ToolName, FILE *F, bool ShouldByteSwap, std::vector &Data) { // Read the number of entries... unsigned NumEntries; if (fread(&NumEntries, sizeof(unsigned), 1, F) != 1) { errs() << ToolName << ": data packet truncated!\n"; perror(0); exit(1); } NumEntries = ByteSwap(NumEntries, ShouldByteSwap); // Read the counts... std::vector TempSpace(NumEntries); // Read in the block of data... if (fread(&TempSpace[0], sizeof(unsigned)*NumEntries, 1, F) != 1) { errs() << ToolName << ": data packet truncated!\n"; perror(0); exit(1); } // Make sure we have enough space... The space is initialised to -1 to // facitiltate the loading of missing values for OptimalEdgeProfiling. if (Data.size() < NumEntries) Data.resize(NumEntries, ~0U); // Accumulate the data we just read into the data. if (!ShouldByteSwap) { for (unsigned i = 0; i != NumEntries; ++i) { Data[i] = AddCounts(TempSpace[i], Data[i]); } } else { for (unsigned i = 0; i != NumEntries; ++i) { Data[i] = AddCounts(ByteSwap(TempSpace[i], true), Data[i]); } } } // ProfileInfoLoader ctor - Read the specified profiling data file, exiting the // program if the file is invalid or broken. // ProfileInfoLoader::ProfileInfoLoader(const char *ToolName, const std::string &Filename, Module &TheModule) : Filename(Filename), M(TheModule), Warned(false) { FILE *F = fopen(Filename.c_str(), "rb"); if (F == 0) { errs() << ToolName << ": Error opening '" << Filename << "': "; perror(0); exit(1); } // Keep reading packets until we run out of them. unsigned PacketType; while (fread(&PacketType, sizeof(unsigned), 1, F) == 1) { // If the low eight bits of the packet are zero, we must be dealing with an // endianness mismatch. Byteswap all words read from the profiling // information. bool ShouldByteSwap = (char)PacketType == 0; PacketType = ByteSwap(PacketType, ShouldByteSwap); switch (PacketType) { case ArgumentInfo: { unsigned ArgLength; if (fread(&ArgLength, sizeof(unsigned), 1, F) != 1) { errs() << ToolName << ": arguments packet truncated!\n"; perror(0); exit(1); } ArgLength = ByteSwap(ArgLength, ShouldByteSwap); // Read in the arguments... std::vector Chars(ArgLength+4); if (ArgLength) if (fread(&Chars[0], (ArgLength+3) & ~3, 1, F) != 1) { errs() << ToolName << ": arguments packet truncated!\n"; perror(0); exit(1); } CommandLines.push_back(std::string(&Chars[0], &Chars[ArgLength])); break; } case FunctionInfo: ReadProfilingBlock(ToolName, F, ShouldByteSwap, FunctionCounts); break; case BlockInfo: ReadProfilingBlock(ToolName, F, ShouldByteSwap, BlockCounts); break; case EdgeInfo: ReadProfilingBlock(ToolName, F, ShouldByteSwap, EdgeCounts); break; case OptEdgeInfo: ReadProfilingBlock(ToolName, F, ShouldByteSwap, OptimalEdgeCounts); break; case BBTraceInfo: ReadProfilingBlock(ToolName, F, ShouldByteSwap, BBTrace); break; default: errs() << ToolName << ": Unknown packet type #" << PacketType << "!\n"; exit(1); } } fclose(F); }