llvm-6502/lib/Target/SparcV9/MappingInfo.cpp

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