tools/gccld/GenerateCode.cpp - fp2-dev/platform/external/llvm - Gitiles

 //===- GenerateCode.cpp - Functions for generating executable files  ------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file was developed by the LLVM research group and is distributed under
 // the University of Illinois Open Source License. See LICENSE.TXT for details.
 //
 //===----------------------------------------------------------------------===//
 //
 // This file contains functions for generating executable files once linking
 // has finished.  This includes generating a shell script to run the JIT or
 // a native executable derived from the bytecode.
 //
 //===----------------------------------------------------------------------===//

 #include "gccld.h"
 #include "llvm/System/Program.h"
 #include "llvm/Module.h"
 #include "llvm/PassManager.h"
 #include "llvm/Analysis/LoadValueNumbering.h"
 #include "llvm/Analysis/Passes.h"
 #include "llvm/Analysis/Verifier.h"
 #include "llvm/Bytecode/Archive.h"
 #include "llvm/Bytecode/WriteBytecodePass.h"
 #include "llvm/Target/TargetData.h"
 #include "llvm/Transforms/IPO.h"
 #include "llvm/Transforms/Scalar.h"
 #include "llvm/Support/SystemUtils.h"
 #include "llvm/Support/CommandLine.h"

 using namespace llvm;

 namespace {
   cl::opt<bool>
   DisableInline("disable-inlining", cl::desc("Do not run the inliner pass"));

   cl::opt<bool>
   Verify("verify", cl::desc("Verify intermediate results of all passes"));

   cl::opt<bool>
   DisableOptimizations("disable-opt",
                        cl::desc("Do not run any optimization passes"));
 }

 /// CopyEnv - This function takes an array of environment variables and makes a
 /// copy of it.  This copy can then be manipulated any way the caller likes
 /// without affecting the process's real environment.
 ///
 /// Inputs:
 ///  envp - An array of C strings containing an environment.
 ///
 /// Return value:
 ///  NULL - An error occurred.
 ///
 ///  Otherwise, a pointer to a new array of C strings is returned.  Every string
 ///  in the array is a duplicate of the one in the original array (i.e. we do
 ///  not copy the char *'s from one array to another).
 ///
 static char ** CopyEnv(char ** const envp) {
   // Count the number of entries in the old list;
   unsigned entries;   // The number of entries in the old environment list
   for (entries = 0; envp[entries] != NULL; entries++)
     /*empty*/;

   // Add one more entry for the NULL pointer that ends the list.
   ++entries;

   // If there are no entries at all, just return NULL.
   if (entries == 0)
     return NULL;

   // Allocate a new environment list.
   char **newenv = new char* [entries];
   if ((newenv = new char* [entries]) == NULL)
     return NULL;

   // Make a copy of the list.  Don't forget the NULL that ends the list.
   entries = 0;
   while (envp[entries] != NULL) {
     newenv[entries] = new char[strlen (envp[entries]) + 1];
     strcpy (newenv[entries], envp[entries]);
     ++entries;
   }
   newenv[entries] = NULL;

   return newenv;
 }


 /// RemoveEnv - Remove the specified environment variable from the environment
 /// array.
 ///
 /// Inputs:
 ///  name - The name of the variable to remove.  It cannot be NULL.
 ///  envp - The array of environment variables.  It cannot be NULL.
 ///
 /// Notes:
 ///  This is mainly done because functions to remove items from the environment
 ///  are not available across all platforms.  In particular, Solaris does not
 ///  seem to have an unsetenv() function or a setenv() function (or they are
 ///  undocumented if they do exist).
 ///
 static void RemoveEnv(const char * name, char ** const envp) {
   for (unsigned index=0; envp[index] != NULL; index++) {
     // Find the first equals sign in the array and make it an EOS character.
     char *p = strchr (envp[index], '=');
     if (p == NULL)
       continue;
     else
       *p = '\0';

     // Compare the two strings.  If they are equal, zap this string.
     // Otherwise, restore it.
     if (!strcmp(name, envp[index]))
       *envp[index] = '\0';
     else
       *p = '=';
   }
 }

 static void dumpArgs(const char **args) {
   std::cerr << *args++;
   while (*args)
     std::cerr << ' ' << *args++;
   std::cerr << '\n' << std::flush;
 }

 static inline void addPass(PassManager &PM, Pass *P) {
   // Add the pass to the pass manager...
   PM.add(P);

   // If we are verifying all of the intermediate steps, add the verifier...
   if (Verify) PM.add(createVerifierPass());
 }

 static bool isBytecodeLibrary(const sys::Path &FullPath) {
   // Check for a bytecode file
   if (FullPath.isBytecodeFile()) return true;
   // Check for a dynamic library file
   if (FullPath.isDynamicLibrary()) return false;
   // Check for a true bytecode archive file
   if (FullPath.isArchive() ) {
     std::string ErrorMessage;
     Archive* ar = Archive::OpenAndLoadSymbols( FullPath, &ErrorMessage );
     return ar->isBytecodeArchive();
   }
   return false;
 }

 static bool isBytecodeLPath(const std::string &LibPath) {
   sys::Path LPath(LibPath);

   // Make sure it exists and is a directory
   sys::FileStatus Status;
   if (LPath.getFileStatus(Status) || !Status.isDir)
     return false;

   // Grab the contents of the -L path
   std::set<sys::Path> Files;
   LPath.getDirectoryContents(Files);

   // Iterate over the contents one by one to determine
   // if this -L path has any bytecode shared libraries
   // or archives
   std::set<sys::Path>::iterator File = Files.begin();
   std::string dllsuffix = sys::Path::GetDLLSuffix();
   for (; File != Files.end(); ++File) {

     // Not a file?
     if (File->getFileStatus(Status) || Status.isDir)
       continue;

     std::string path = File->toString();

     // Check for an ending '.dll', '.so' or '.a' suffix as all
     // other files are not of interest to us here
     if (path.find(dllsuffix, path.size()-dllsuffix.size()) == std::string::npos
         && path.find(".a", path.size()-2) == std::string::npos)
       continue;

     // Finally, check to see if the file is a true bytecode file
     if (isBytecodeLibrary(*File))
       return true;
   }
   return false;
 }

 /// GenerateBytecode - generates a bytecode file from the specified module.
 ///
 /// Inputs:
 ///  M           - The module for which bytecode should be generated.
 ///  StripLevel  - 2 if we should strip all symbols, 1 if we should strip
 ///                debug info.
 ///  Internalize - Flags whether all symbols should be marked internal.
 ///  Out         - Pointer to file stream to which to write the output.
 ///
 /// Returns non-zero value on error.
 ///
 int llvm::GenerateBytecode(Module *M, int StripLevel, bool Internalize,
                            std::ostream *Out) {
   // In addition to just linking the input from GCC, we also want to spiff it up
   // a little bit.  Do this now.
   PassManager Passes;

   if (Verify) Passes.add(createVerifierPass());

   // Add an appropriate TargetData instance for this module...
   addPass(Passes, new TargetData(M));

   // Often if the programmer does not specify proper prototypes for the
   // functions they are calling, they end up calling a vararg version of the
   // function that does not get a body filled in (the real function has typed
   // arguments).  This pass merges the two functions.
   addPass(Passes, createFunctionResolvingPass());

   if (!DisableOptimizations) {
     // Now that composite has been compiled, scan through the module, looking
     // for a main function.  If main is defined, mark all other functions
     // internal.
     addPass(Passes, createInternalizePass(Internalize));

     // Now that we internalized some globals, see if we can hack on them!
     addPass(Passes, createGlobalOptimizerPass());

     // Linking modules together can lead to duplicated global constants, only
     // keep one copy of each constant...
     addPass(Passes, createConstantMergePass());

     // Propagate constants at call sites into the functions they call.
     addPass(Passes, createIPSCCPPass());

     // Remove unused arguments from functions...
     addPass(Passes, createDeadArgEliminationPass());

     if (!DisableInline)
       addPass(Passes, createFunctionInliningPass()); // Inline small functions

     addPass(Passes, createPruneEHPass());            // Remove dead EH info
     addPass(Passes, createGlobalOptimizerPass());    // Optimize globals again.
     addPass(Passes, createGlobalDCEPass());          // Remove dead functions

     // If we didn't decide to inline a function, check to see if we can
     // transform it to pass arguments by value instead of by reference.
     addPass(Passes, createArgumentPromotionPass());

     // The IPO passes may leave cruft around.  Clean up after them.
     addPass(Passes, createInstructionCombiningPass());

     addPass(Passes, createScalarReplAggregatesPass()); // Break up allocas

     // Run a few AA driven optimizations here and now, to cleanup the code.
     addPass(Passes, createGlobalsModRefPass());      // IP alias analysis

     addPass(Passes, createLICMPass());               // Hoist loop invariants
     addPass(Passes, createLoadValueNumberingPass()); // GVN for load instrs
     addPass(Passes, createGCSEPass());               // Remove common subexprs
     addPass(Passes, createDeadStoreEliminationPass()); // Nuke dead stores

     // Cleanup and simplify the code after the scalar optimizations.
     addPass(Passes, createInstructionCombiningPass());

     // Delete basic blocks, which optimization passes may have killed...
     addPass(Passes, createCFGSimplificationPass());

     // Now that we have optimized the program, discard unreachable functions...
     addPass(Passes, createGlobalDCEPass());
   }

   // If the -s or -S command line options were specified, strip the symbols out
   // of the resulting program to make it smaller.  -s and -S are GLD options
   // that we are supporting.
   if (StripLevel)
     addPass(Passes, createStripSymbolsPass(StripLevel == 1));

   // Make sure everything is still good.
   Passes.add(createVerifierPass());

   // Add the pass that writes bytecode to the output file...
   addPass(Passes, new WriteBytecodePass(Out));

   // Run our queue of passes all at once now, efficiently.
   Passes.run(*M);

   return 0;
 }

 /// GenerateAssembly - generates a native assembly language source file from the
 /// specified bytecode file.
 ///
 /// Inputs:
 ///  InputFilename  - The name of the output bytecode file.
 ///  OutputFilename - The name of the file to generate.
 ///  llc            - The pathname to use for LLC.
 ///
 /// Return non-zero value on error.
 ///
 int llvm::GenerateAssembly(const std::string &OutputFilename,
                            const std::string &InputFilename,
                            const sys::Path &llc,
                            std::string& ErrMsg,
                            bool Verbose) {
   // Run LLC to convert the bytecode file into assembly code.
   std::vector<const char*> args;
   args.push_back(llc.c_str());
   args.push_back("-f");
   args.push_back("-o");
   args.push_back(OutputFilename.c_str());
   args.push_back(InputFilename.c_str());
   args.push_back(0);
   if (Verbose) dumpArgs(&args[0]);
   return sys::Program::ExecuteAndWait(llc, &args[0],0,0,0,&ErrMsg);
 }

 /// GenerateCFile - generates a C source file from the specified bytecode file.
 int llvm::GenerateCFile(const std::string &OutputFile,
                         const std::string &InputFile,
                         const sys::Path &llc,
                         std::string& ErrMsg,
                         bool Verbose) {
   // Run LLC to convert the bytecode file into C.
   std::vector<const char*> args;
   args.push_back(llc.c_str());
   args.push_back("-march=c");
   args.push_back("-f");
   args.push_back("-o");
   args.push_back(OutputFile.c_str());
   args.push_back(InputFile.c_str());
   args.push_back(0);
   if (Verbose) dumpArgs(&args[0]);
   return sys::Program::ExecuteAndWait(llc, &args[0],0,0,0,&ErrMsg);
 }

 /// GenerateNative - generates a native executable file from the specified
 /// assembly source file.
 ///
 /// Inputs:
 ///  InputFilename  - The name of the output bytecode file.
 ///  OutputFilename - The name of the file to generate.
 ///  Libraries      - The list of libraries with which to link.
 ///  gcc            - The pathname to use for GGC.
 ///  envp           - A copy of the process's current environment.
 ///
 /// Outputs:
 ///  None.
 ///
 /// Returns non-zero value on error.
 ///
 int llvm::GenerateNative(const std::string &OutputFilename,
                          const std::string &InputFilename,
                          const std::vector<std::string> &LibPaths,
                          const std::vector<std::string> &Libraries,
                          const sys::Path &gcc, char ** const envp,
                          bool Shared,
                          bool ExportAllAsDynamic,
                          const std::vector<std::string> &RPaths,
                          const std::string &SOName,
                          std::string& ErrMsg,
                          bool Verbose) {
   // Remove these environment variables from the environment of the
   // programs that we will execute.  It appears that GCC sets these
   // environment variables so that the programs it uses can configure
   // themselves identically.
   //
   // However, when we invoke GCC below, we want it to use its normal
   // configuration.  Hence, we must sanitize its environment.
   char ** clean_env = CopyEnv(envp);
   if (clean_env == NULL)
     return 1;
   RemoveEnv("LIBRARY_PATH", clean_env);
   RemoveEnv("COLLECT_GCC_OPTIONS", clean_env);
   RemoveEnv("GCC_EXEC_PREFIX", clean_env);
   RemoveEnv("COMPILER_PATH", clean_env);
   RemoveEnv("COLLECT_GCC", clean_env);


   // Run GCC to assemble and link the program into native code.
   //
   // Note:
   //  We can't just assemble and link the file with the system assembler
   //  and linker because we don't know where to put the _start symbol.
   //  GCC mysteriously knows how to do it.
   std::vector<const char*> args;
   args.push_back(gcc.c_str());
   args.push_back("-fno-strict-aliasing");
   args.push_back("-O3");
   args.push_back("-o");
   args.push_back(OutputFilename.c_str());
   args.push_back(InputFilename.c_str());

   // StringsToDelete - We don't want to call c_str() on temporary strings.
   // If we need a temporary string, copy it here so that the memory is not
   // reclaimed until after the exec call.  All of these strings are allocated
   // with strdup.
   std::vector<char*> StringsToDelete;

   if (Shared) args.push_back("-shared");
   if (ExportAllAsDynamic) args.push_back("-export-dynamic");
   if (!RPaths.empty()) {
     for (std::vector<std::string>::const_iterator I = RPaths.begin(),
         E = RPaths.end(); I != E; I++) {
       std::string rp = "-Wl,-rpath," + *I;
       StringsToDelete.push_back(strdup(rp.c_str()));
       args.push_back(StringsToDelete.back());
     }
   }
   if (!SOName.empty()) {
     std::string so = "-Wl,-soname," + SOName;
     StringsToDelete.push_back(strdup(so.c_str()));
     args.push_back(StringsToDelete.back());
   }

   // Add in the libpaths to find the libraries.
   //
   // Note:
   //  When gccld is called from the llvm-gxx frontends, the -L paths for
   //  the LLVM cfrontend install paths are appended.  We don't want the
   //  native linker to use these -L paths as they contain bytecode files.
   //  Further, we don't want any -L paths that contain bytecode shared
   //  libraries or true bytecode archive files.  We omit them in all such
   //  cases.
   for (unsigned index = 0; index < LibPaths.size(); index++)
     if (!isBytecodeLPath(LibPaths[index])) {
       std::string Tmp = "-L"+LibPaths[index];
       StringsToDelete.push_back(strdup(Tmp.c_str()));
       args.push_back(StringsToDelete.back());
     }

   // Add in the libraries to link.
   for (unsigned index = 0; index < Libraries.size(); index++)
     // HACK: If this is libg, discard it.  This gets added by the compiler
     // driver when doing: 'llvm-gcc main.c -Wl,-native -o a.out -g'. Note that
     // this should really be fixed by changing the llvm-gcc compiler driver.
     if (Libraries[index] != "crtend" && Libraries[index] != "g") {
       std::string Tmp = "-l"+Libraries[index];
       StringsToDelete.push_back(strdup(Tmp.c_str()));
       args.push_back(StringsToDelete.back());
     }
   args.push_back(0); // Null terminate.

   // Run the compiler to assembly and link together the program.
   if (Verbose) dumpArgs(&args[0]);
   int Res = sys::Program::ExecuteAndWait(
       gcc, &args[0],(const char**)clean_env,0,0,&ErrMsg);

   delete [] clean_env;

   while (!StringsToDelete.empty()) {
     free(StringsToDelete.back());
     StringsToDelete.pop_back();
   }
   return Res;
 }
	//===- GenerateCode.cpp - Functions for generating executable files ------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file was developed by the LLVM research group and is distributed under
	// the University of Illinois Open Source License. See LICENSE.TXT for details.
	//
	//===----------------------------------------------------------------------===//
	//
	// This file contains functions for generating executable files once linking
	// has finished. This includes generating a shell script to run the JIT or
	// a native executable derived from the bytecode.
	//
	//===----------------------------------------------------------------------===//

	#include "gccld.h"
	#include "llvm/System/Program.h"
	#include "llvm/Module.h"
	#include "llvm/PassManager.h"
	#include "llvm/Analysis/LoadValueNumbering.h"
	#include "llvm/Analysis/Passes.h"
	#include "llvm/Analysis/Verifier.h"
	#include "llvm/Bytecode/Archive.h"
	#include "llvm/Bytecode/WriteBytecodePass.h"
	#include "llvm/Target/TargetData.h"
	#include "llvm/Transforms/IPO.h"
	#include "llvm/Transforms/Scalar.h"
	#include "llvm/Support/SystemUtils.h"
	#include "llvm/Support/CommandLine.h"

	using namespace llvm;

	namespace {
	cl::opt<bool>
	DisableInline("disable-inlining", cl::desc("Do not run the inliner pass"));

	cl::opt<bool>
	Verify("verify", cl::desc("Verify intermediate results of all passes"));

	cl::opt<bool>
	DisableOptimizations("disable-opt",
	cl::desc("Do not run any optimization passes"));
	}

	/// CopyEnv - This function takes an array of environment variables and makes a
	/// copy of it. This copy can then be manipulated any way the caller likes
	/// without affecting the process's real environment.
	///
	/// Inputs:
	/// envp - An array of C strings containing an environment.
	///
	/// Return value:
	/// NULL - An error occurred.
	///
	/// Otherwise, a pointer to a new array of C strings is returned. Every string
	/// in the array is a duplicate of the one in the original array (i.e. we do
	/// not copy the char *'s from one array to another).
	///
	static char CopyEnv(char const envp) {
	// Count the number of entries in the old list;
	unsigned entries; // The number of entries in the old environment list
	for (entries = 0; envp[entries] != NULL; entries++)
	/empty/;

	// Add one more entry for the NULL pointer that ends the list.
	++entries;

	// If there are no entries at all, just return NULL.
	if (entries == 0)
	return NULL;

	// Allocate a new environment list.
	char *newenv = new char [entries];
	if ((newenv = new char* [entries]) == NULL)
	return NULL;

	// Make a copy of the list. Don't forget the NULL that ends the list.
	entries = 0;
	while (envp[entries] != NULL) {
	newenv[entries] = new char[strlen (envp[entries]) + 1];
	strcpy (newenv[entries], envp[entries]);
	++entries;
	}
	newenv[entries] = NULL;

	return newenv;
	}


	/// RemoveEnv - Remove the specified environment variable from the environment
	/// array.
	///
	/// Inputs:
	/// name - The name of the variable to remove. It cannot be NULL.
	/// envp - The array of environment variables. It cannot be NULL.
	///
	/// Notes:
	/// This is mainly done because functions to remove items from the environment
	/// are not available across all platforms. In particular, Solaris does not
	/// seem to have an unsetenv() function or a setenv() function (or they are
	/// undocumented if they do exist).
	///
	static void RemoveEnv(const char * name, char ** const envp) {
	for (unsigned index=0; envp[index] != NULL; index++) {
	// Find the first equals sign in the array and make it an EOS character.
	char *p = strchr (envp[index], '=');
	if (p == NULL)
	continue;
	else
	*p = '\0';

	// Compare the two strings. If they are equal, zap this string.
	// Otherwise, restore it.
	if (!strcmp(name, envp[index]))
	*envp[index] = '\0';
	else
	*p = '=';
	}
	}

	static void dumpArgs(const char **args) {
	std::cerr << *args++;
	while (*args)
	std::cerr << ' ' << *args++;
	std::cerr << '\n' << std::flush;
	}

	static inline void addPass(PassManager &PM, Pass *P) {
	// Add the pass to the pass manager...
	PM.add(P);

	// If we are verifying all of the intermediate steps, add the verifier...
	if (Verify) PM.add(createVerifierPass());
	}

	static bool isBytecodeLibrary(const sys::Path &FullPath) {
	// Check for a bytecode file
	if (FullPath.isBytecodeFile()) return true;
	// Check for a dynamic library file
	if (FullPath.isDynamicLibrary()) return false;
	// Check for a true bytecode archive file
	if (FullPath.isArchive() ) {
	std::string ErrorMessage;
	Archive* ar = Archive::OpenAndLoadSymbols( FullPath, &ErrorMessage );
	return ar->isBytecodeArchive();
	}
	return false;
	}

	static bool isBytecodeLPath(const std::string &LibPath) {
	sys::Path LPath(LibPath);

	// Make sure it exists and is a directory
	sys::FileStatus Status;
	if (LPath.getFileStatus(Status) \|\| !Status.isDir)
	return false;

	// Grab the contents of the -L path
	std::set<sys::Path> Files;
	LPath.getDirectoryContents(Files);

	// Iterate over the contents one by one to determine
	// if this -L path has any bytecode shared libraries
	// or archives
	std::set<sys::Path>::iterator File = Files.begin();
	std::string dllsuffix = sys::Path::GetDLLSuffix();
	for (; File != Files.end(); ++File) {

	// Not a file?
	if (File->getFileStatus(Status) \|\| Status.isDir)
	continue;

	std::string path = File->toString();

	// Check for an ending '.dll', '.so' or '.a' suffix as all
	// other files are not of interest to us here
	if (path.find(dllsuffix, path.size()-dllsuffix.size()) == std::string::npos
	&& path.find(".a", path.size()-2) == std::string::npos)
	continue;

	// Finally, check to see if the file is a true bytecode file
	if (isBytecodeLibrary(*File))
	return true;
	}
	return false;
	}

	/// GenerateBytecode - generates a bytecode file from the specified module.
	///
	/// Inputs:
	/// M - The module for which bytecode should be generated.
	/// StripLevel - 2 if we should strip all symbols, 1 if we should strip
	/// debug info.
	/// Internalize - Flags whether all symbols should be marked internal.
	/// Out - Pointer to file stream to which to write the output.
	///
	/// Returns non-zero value on error.
	///
	int llvm::GenerateBytecode(Module *M, int StripLevel, bool Internalize,
	std::ostream *Out) {
	// In addition to just linking the input from GCC, we also want to spiff it up
	// a little bit. Do this now.
	PassManager Passes;

	if (Verify) Passes.add(createVerifierPass());

	// Add an appropriate TargetData instance for this module...
	addPass(Passes, new TargetData(M));

	// Often if the programmer does not specify proper prototypes for the
	// functions they are calling, they end up calling a vararg version of the
	// function that does not get a body filled in (the real function has typed
	// arguments). This pass merges the two functions.
	addPass(Passes, createFunctionResolvingPass());

	if (!DisableOptimizations) {
	// Now that composite has been compiled, scan through the module, looking
	// for a main function. If main is defined, mark all other functions
	// internal.
	addPass(Passes, createInternalizePass(Internalize));

	// Now that we internalized some globals, see if we can hack on them!
	addPass(Passes, createGlobalOptimizerPass());

	// Linking modules together can lead to duplicated global constants, only
	// keep one copy of each constant...
	addPass(Passes, createConstantMergePass());

	// Propagate constants at call sites into the functions they call.
	addPass(Passes, createIPSCCPPass());

	// Remove unused arguments from functions...
	addPass(Passes, createDeadArgEliminationPass());

	if (!DisableInline)
	addPass(Passes, createFunctionInliningPass()); // Inline small functions

	addPass(Passes, createPruneEHPass()); // Remove dead EH info
	addPass(Passes, createGlobalOptimizerPass()); // Optimize globals again.
	addPass(Passes, createGlobalDCEPass()); // Remove dead functions

	// If we didn't decide to inline a function, check to see if we can
	// transform it to pass arguments by value instead of by reference.
	addPass(Passes, createArgumentPromotionPass());

	// The IPO passes may leave cruft around. Clean up after them.
	addPass(Passes, createInstructionCombiningPass());

	addPass(Passes, createScalarReplAggregatesPass()); // Break up allocas

	// Run a few AA driven optimizations here and now, to cleanup the code.
	addPass(Passes, createGlobalsModRefPass()); // IP alias analysis

	addPass(Passes, createLICMPass()); // Hoist loop invariants
	addPass(Passes, createLoadValueNumberingPass()); // GVN for load instrs
	addPass(Passes, createGCSEPass()); // Remove common subexprs
	addPass(Passes, createDeadStoreEliminationPass()); // Nuke dead stores

	// Cleanup and simplify the code after the scalar optimizations.
	addPass(Passes, createInstructionCombiningPass());

	// Delete basic blocks, which optimization passes may have killed...
	addPass(Passes, createCFGSimplificationPass());

	// Now that we have optimized the program, discard unreachable functions...
	addPass(Passes, createGlobalDCEPass());
	}

	// If the -s or -S command line options were specified, strip the symbols out
	// of the resulting program to make it smaller. -s and -S are GLD options
	// that we are supporting.
	if (StripLevel)
	addPass(Passes, createStripSymbolsPass(StripLevel == 1));

	// Make sure everything is still good.
	Passes.add(createVerifierPass());

	// Add the pass that writes bytecode to the output file...
	addPass(Passes, new WriteBytecodePass(Out));

	// Run our queue of passes all at once now, efficiently.
	Passes.run(*M);

	return 0;
	}

	/// GenerateAssembly - generates a native assembly language source file from the
	/// specified bytecode file.
	///
	/// Inputs:
	/// InputFilename - The name of the output bytecode file.
	/// OutputFilename - The name of the file to generate.
	/// llc - The pathname to use for LLC.
	///
	/// Return non-zero value on error.
	///
	int llvm::GenerateAssembly(const std::string &OutputFilename,
	const std::string &InputFilename,
	const sys::Path &llc,
	std::string& ErrMsg,
	bool Verbose) {
	// Run LLC to convert the bytecode file into assembly code.
	std::vector<const char*> args;
	args.push_back(llc.c_str());
	args.push_back("-f");
	args.push_back("-o");
	args.push_back(OutputFilename.c_str());
	args.push_back(InputFilename.c_str());
	args.push_back(0);
	if (Verbose) dumpArgs(&args[0]);
	return sys::Program::ExecuteAndWait(llc, &args[0],0,0,0,&ErrMsg);
	}

	/// GenerateCFile - generates a C source file from the specified bytecode file.
	int llvm::GenerateCFile(const std::string &OutputFile,
	const std::string &InputFile,
	const sys::Path &llc,
	std::string& ErrMsg,
	bool Verbose) {
	// Run LLC to convert the bytecode file into C.
	std::vector<const char*> args;
	args.push_back(llc.c_str());
	args.push_back("-march=c");
	args.push_back("-f");
	args.push_back("-o");
	args.push_back(OutputFile.c_str());
	args.push_back(InputFile.c_str());
	args.push_back(0);
	if (Verbose) dumpArgs(&args[0]);
	return sys::Program::ExecuteAndWait(llc, &args[0],0,0,0,&ErrMsg);
	}

	/// GenerateNative - generates a native executable file from the specified
	/// assembly source file.
	///
	/// Inputs:
	/// InputFilename - The name of the output bytecode file.
	/// OutputFilename - The name of the file to generate.
	/// Libraries - The list of libraries with which to link.
	/// gcc - The pathname to use for GGC.
	/// envp - A copy of the process's current environment.
	///
	/// Outputs:
	/// None.
	///
	/// Returns non-zero value on error.
	///
	int llvm::GenerateNative(const std::string &OutputFilename,
	const std::string &InputFilename,
	const std::vector<std::string> &LibPaths,
	const std::vector<std::string> &Libraries,
	const sys::Path &gcc, char ** const envp,
	bool Shared,
	bool ExportAllAsDynamic,
	const std::vector<std::string> &RPaths,
	const std::string &SOName,
	std::string& ErrMsg,
	bool Verbose) {
	// Remove these environment variables from the environment of the
	// programs that we will execute. It appears that GCC sets these
	// environment variables so that the programs it uses can configure
	// themselves identically.
	//
	// However, when we invoke GCC below, we want it to use its normal
	// configuration. Hence, we must sanitize its environment.
	char ** clean_env = CopyEnv(envp);
	if (clean_env == NULL)
	return 1;
	RemoveEnv("LIBRARY_PATH", clean_env);
	RemoveEnv("COLLECT_GCC_OPTIONS", clean_env);
	RemoveEnv("GCC_EXEC_PREFIX", clean_env);
	RemoveEnv("COMPILER_PATH", clean_env);
	RemoveEnv("COLLECT_GCC", clean_env);


	// Run GCC to assemble and link the program into native code.
	//
	// Note:
	// We can't just assemble and link the file with the system assembler
	// and linker because we don't know where to put the _start symbol.
	// GCC mysteriously knows how to do it.
	std::vector<const char*> args;
	args.push_back(gcc.c_str());
	args.push_back("-fno-strict-aliasing");
	args.push_back("-O3");
	args.push_back("-o");
	args.push_back(OutputFilename.c_str());
	args.push_back(InputFilename.c_str());

	// StringsToDelete - We don't want to call c_str() on temporary strings.
	// If we need a temporary string, copy it here so that the memory is not
	// reclaimed until after the exec call. All of these strings are allocated
	// with strdup.
	std::vector<char*> StringsToDelete;

	if (Shared) args.push_back("-shared");
	if (ExportAllAsDynamic) args.push_back("-export-dynamic");
	if (!RPaths.empty()) {
	for (std::vector<std::string>::const_iterator I = RPaths.begin(),
	E = RPaths.end(); I != E; I++) {
	std::string rp = "-Wl,-rpath," + *I;
	StringsToDelete.push_back(strdup(rp.c_str()));
	args.push_back(StringsToDelete.back());
	}
	}
	if (!SOName.empty()) {
	std::string so = "-Wl,-soname," + SOName;
	StringsToDelete.push_back(strdup(so.c_str()));
	args.push_back(StringsToDelete.back());
	}

	// Add in the libpaths to find the libraries.
	//
	// Note:
	// When gccld is called from the llvm-gxx frontends, the -L paths for
	// the LLVM cfrontend install paths are appended. We don't want the
	// native linker to use these -L paths as they contain bytecode files.
	// Further, we don't want any -L paths that contain bytecode shared
	// libraries or true bytecode archive files. We omit them in all such
	// cases.
	for (unsigned index = 0; index < LibPaths.size(); index++)
	if (!isBytecodeLPath(LibPaths[index])) {
	std::string Tmp = "-L"+LibPaths[index];
	StringsToDelete.push_back(strdup(Tmp.c_str()));
	args.push_back(StringsToDelete.back());
	}

	// Add in the libraries to link.
	for (unsigned index = 0; index < Libraries.size(); index++)
	// HACK: If this is libg, discard it. This gets added by the compiler
	// driver when doing: 'llvm-gcc main.c -Wl,-native -o a.out -g'. Note that
	// this should really be fixed by changing the llvm-gcc compiler driver.
	if (Libraries[index] != "crtend" && Libraries[index] != "g") {
	std::string Tmp = "-l"+Libraries[index];
	StringsToDelete.push_back(strdup(Tmp.c_str()));
	args.push_back(StringsToDelete.back());
	}
	args.push_back(0); // Null terminate.

	// Run the compiler to assembly and link together the program.
	if (Verbose) dumpArgs(&args[0]);
	int Res = sys::Program::ExecuteAndWait(
	gcc, &args[0],(const char**)clean_env,0,0,&ErrMsg);

	delete [] clean_env;

	while (!StringsToDelete.empty()) {
	free(StringsToDelete.back());
	StringsToDelete.pop_back();
	}
	return Res;
	}