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bc5ddca6a2
Update file comment to contain a bunch of the overview mapping-info documentation previously buried within the file. Remove some unnecessary include/using stmts. Rename pass to MappingInfoCollector. Rewrite a lot of it so it doesn't use global instance variables and so it outputs into MappingInfo objects and then dumps those out, instead of going straight to an assembly file. Change name of factory to getMappingInfoCollector. Fold prologue & epilogue writers into MappingInfo methods. lib/Target/Sparc/FInfo.cpp: Correct file comment to reflect above change lib/Target/Sparc/Sparc.cpp: Change name of factory to getMappingInfoCollector. llvm-svn: 6617
243 lines
9.7 KiB
C++
243 lines
9.7 KiB
C++
//===- MappingInfo.cpp - create LLVM info and output to .s file ---------===//
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//
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// This file contains a FunctionPass called MappingInfo,
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// which creates two maps: one between LLVM Instructions and MachineInstrs
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// (the "LLVM I TO MI MAP"), and another between MachineBasicBlocks and
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// MachineInstrs (the "BB TO MI MAP").
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//
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// As a side effect, it outputs this information as .byte directives to
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// the assembly file. The output is designed to survive the SPARC assembler,
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// in order that the Reoptimizer may read it in from memory later when the
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// binary is loaded. Therefore, it may contain some hidden SPARC-architecture
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// dependencies. Currently this question is purely theoretical as the
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// Reoptimizer works only on the SPARC.
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//
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// The LLVM I TO MI MAP consists of a set of information for each
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// BasicBlock in a Function, ordered from begin() to end(). The information
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// for a BasicBlock consists of
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// 1) its (0-based) index in the Function,
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// 2) the number of LLVM Instructions it contains, and
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// 3) information for each Instruction, in sequence from the begin()
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// to the end() of the BasicBlock. The information for an Instruction
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// consists of
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// 1) its (0-based) index in the BasicBlock,
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// 2) the number of MachineInstrs that correspond to that Instruction
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// (as reported by MachineCodeForInstruction), and
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// 3) the MachineInstr number calculated by create_MI_to_number_Key,
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// for each of the MachineInstrs that correspond to that Instruction.
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//
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// The BB TO MI MAP consists of a three-element tuple for each
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// MachineBasicBlock in a function, ordered from begin() to end() of
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// its MachineFunction: first, the index of the MachineBasicBlock in the
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// function; second, the number of the MachineBasicBlock in the function
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// as computed by create_BB_to_MInumber_Key; and third, the number of
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// MachineInstrs in the MachineBasicBlock.
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//
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//===--------------------------------------------------------------------===//
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#include "llvm/Reoptimizer/Mapping/MappingInfo.h"
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#include "llvm/Pass.h"
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#include "llvm/Module.h"
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#include "llvm/CodeGen/MachineInstr.h"
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#include "llvm/CodeGen/MachineFunction.h"
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#include "llvm/CodeGen/MachineCodeForInstruction.h"
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namespace {
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class MappingInfoCollector : public FunctionPass {
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std::ostream &Out;
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public:
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MappingInfoCollector(std::ostream &out) : Out(out){}
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const char *getPassName () const { return "Instr. Mapping Info Collector"; }
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bool runOnFunction(Function &FI);
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typedef std::map<const MachineInstr*, unsigned> InstructionKey;
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private:
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MappingInfo *currentOutputMap;
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std::map<Function *, unsigned> Fkey; // Function # for all functions.
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bool doInitialization(Module &M);
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void create_BB_to_MInumber_Key(Function &FI, InstructionKey &key);
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void create_MI_to_number_Key(Function &FI, InstructionKey &key);
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void buildBBMIMap (Function &FI, MappingInfo &Map);
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void buildLMIMap (Function &FI, MappingInfo &Map);
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void writeNumber(unsigned X);
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void selectOutputMap (MappingInfo &m) { currentOutputMap = &m; }
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void outByte (unsigned char b) { currentOutputMap->outByte (b); }
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};
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}
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/// getMappingInfoCollector -- Static factory method: returns a new
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/// MappingInfoCollector Pass object, which uses OUT as its
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/// output stream for assembly output.
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Pass *getMappingInfoCollector(std::ostream &out){
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return (new MappingInfoCollector(out));
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}
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/// runOnFunction -- Builds up the maps for the given function FI and then
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/// writes them out as assembly code to the current output stream OUT.
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/// This is an entry point to the pass, called by the PassManager.
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bool MappingInfoCollector::runOnFunction(Function &FI) {
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unsigned num = Fkey[&FI]; // Function number for the current function.
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// Create objects to hold the maps.
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MappingInfo LMIMap ("LLVM I TO MI MAP", "LMIMap", num);
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MappingInfo BBMIMap ("BB TO MI MAP", "BBMIMap", num);
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// Now, build the maps.
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buildLMIMap (FI, LMIMap);
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buildBBMIMap (FI, BBMIMap);
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// Now, write out the maps.
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LMIMap.dumpAssembly (Out);
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BBMIMap.dumpAssembly (Out);
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return false;
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}
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/// writeNumber -- Write out the number X as a sequence of .byte
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/// directives to the current output stream Out. This method performs a
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/// run-length encoding of the unsigned integers X that are output.
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void MappingInfoCollector::writeNumber(unsigned X) {
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unsigned i=0;
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do {
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unsigned tmp = X & 127;
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X >>= 7;
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if (X) tmp |= 128;
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outByte (tmp);
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++i;
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} while(X);
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}
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/// doInitialization -- Assign a number to each Function, as follows:
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/// Functions are numbered starting at 0 at the begin() of each Module.
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/// Functions which are External (and thus have 0 basic blocks) are not
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/// inserted into the maps, and are not assigned a number. The side-effect
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/// of this method is to fill in Fkey to contain the mapping from Functions
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/// to numbers. (This method is called automatically by the PassManager.)
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bool MappingInfoCollector::doInitialization(Module &M) {
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unsigned i = 0;
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for (Module::iterator FI = M.begin(), FE = M.end(); FI != FE; ++FI) {
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if (FI->isExternal()) continue;
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Fkey[FI] = i;
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++i;
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}
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return false; // Success.
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}
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/// create_BB_to_MInumber_Key -- Assign a number to each MachineBasicBlock
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/// in the given Function, as follows: Numbering starts at zero in each
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/// Function. MachineBasicBlocks are numbered from begin() to end()
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/// in the Function's corresponding MachineFunction. Each successive
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/// MachineBasicBlock increments the numbering by the number of instructions
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/// it contains. The side-effect of this method is to fill in the paramete
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/// KEY with the mapping of MachineBasicBlocks to numbers. KEY
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/// is keyed on MachineInstrs, so each MachineBasicBlock is represented
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/// therein by its first MachineInstr.
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void MappingInfoCollector::create_BB_to_MInumber_Key(Function &FI,
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InstructionKey &key) {
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unsigned i = 0;
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MachineFunction &MF = MachineFunction::get(&FI);
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for (MachineFunction::iterator BI = MF.begin(), BE = MF.end();
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BI != BE; ++BI) {
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MachineBasicBlock &miBB = *BI;
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key[miBB[0]] = i;
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i = i+(miBB.size());
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}
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}
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/// create_MI_to_number_Key -- Assign a number to each MachineInstr
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/// in the given Function with respect to its enclosing MachineBasicBlock, as
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/// follows: Numberings start at 0 in each MachineBasicBlock. MachineInstrs
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/// are numbered from begin() to end() in their MachineBasicBlock. Each
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/// MachineInstr is numbered, then the numbering is incremented by 1. The
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/// side-effect of this method is to fill in the parameter KEY
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/// with the mapping from MachineInstrs to numbers.
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void MappingInfoCollector::create_MI_to_number_Key(Function &FI,
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InstructionKey &key) {
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MachineFunction &MF = MachineFunction::get(&FI);
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for (MachineFunction::iterator BI=MF.begin(), BE=MF.end(); BI != BE; ++BI) {
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MachineBasicBlock &miBB = *BI;
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unsigned j = 0;
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for(MachineBasicBlock::iterator miI = miBB.begin(), miE = miBB.end();
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miI != miE; ++miI, ++j) {
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key[*miI] = j;
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}
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}
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}
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/// buildBBMIMap -- Build the BB TO MI MAP for the function FI,
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/// and save it into the parameter MAP.
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void MappingInfoCollector::buildBBMIMap(Function &FI, MappingInfo &Map) {
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unsigned bb = 0;
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// First build temporary table used to write out the map.
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InstructionKey BBkey;
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create_BB_to_MInumber_Key(FI, BBkey);
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selectOutputMap (Map);
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MachineFunction &MF = MachineFunction::get(&FI);
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for (MachineFunction::iterator BI = MF.begin(), BE = MF.end();
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BI != BE; ++BI, ++bb) {
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MachineBasicBlock &miBB = *BI;
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writeNumber(bb);
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writeNumber(BBkey[miBB[0]]);
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writeNumber(miBB.size());
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}
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}
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/// buildLMIMap -- Build the LLVM I TO MI MAP for the function FI,
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/// and save it into the parameter MAP.
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void MappingInfoCollector::buildLMIMap(Function &FI, MappingInfo &Map) {
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unsigned bb = 0;
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// First build temporary table used to write out the map.
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InstructionKey MIkey;
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create_MI_to_number_Key(FI, MIkey);
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selectOutputMap (Map);
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for (Function::iterator BI = FI.begin(), BE = FI.end();
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BI != BE; ++BI, ++bb) {
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unsigned li = 0;
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writeNumber(bb);
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writeNumber(BI->size());
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for (BasicBlock::iterator II = BI->begin(), IE = BI->end(); II != IE;
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++II, ++li) {
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MachineCodeForInstruction& miI = MachineCodeForInstruction::get(II);
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writeNumber(li);
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writeNumber(miI.size());
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for (MachineCodeForInstruction::iterator miII = miI.begin(),
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miIE = miI.end(); miII != miIE; ++miII) {
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writeNumber(MIkey[*miII]);
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}
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}
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}
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}
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void MappingInfo::byteVector::dumpAssembly (std::ostream &Out) {
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for (iterator i = begin (), e = end (); i != e; ++i)
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Out << ".byte " << (int)*i << "\n";
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}
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void MappingInfo::dumpAssembly (std::ostream &Out) {
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// Prologue:
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// Output a comment describing the map.
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Out << "!" << comment << "\n";
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// Switch the current section to .rodata in the assembly output:
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Out << "\t.section \".rodata\"\n\t.align 8\n";
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// Output a global symbol naming the map:
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Out << "\t.global " << symbolPrefix << functionNumber << "\n";
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Out << "\t.type " << symbolPrefix << functionNumber << ",#object\n";
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Out << symbolPrefix << functionNumber << ":\n";
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// Output a word containing the length of the map:
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Out << "\t.word .end_" << symbolPrefix << functionNumber << "-"
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<< symbolPrefix << functionNumber << "\n";
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// Output the map data itself:
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bytes.dumpAssembly (Out);
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// Epilogue:
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// Output a local symbol marking the end of the map:
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Out << ".end_" << symbolPrefix << functionNumber << ":\n";
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// Output size directive giving the size of the map:
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Out << "\t.size " << symbolPrefix << functionNumber << ", .end_"
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<< symbolPrefix << functionNumber << "-" << symbolPrefix
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<< functionNumber << "\n\n";
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}
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