final/runtime/src/extractExternal.cpp - openmp - Git at Google

 /*
  * extractExternal.cpp
  */


 //===----------------------------------------------------------------------===//
 //
 //                     The LLVM Compiler Infrastructure
 //
 // This file is dual licensed under the MIT and the University of Illinois Open
 // Source Licenses. See LICENSE.txt for details.
 //
 //===----------------------------------------------------------------------===//


 #include <fstream>
 #include <iostream>
 #include <map>
 #include <set>
 #include <stdlib.h>
 #include <string>
 #include <strstream>

 /* Given a set of n object files h ('external' object files) and a set of m
    object files o ('internal' object files),
    1. Determines r, the subset of h that o depends on, directly or indirectly
    2. Removes the files in h - r from the file system
    3. For each external symbol defined in some file in r, rename it in r U o
       by prefixing it with "__kmp_external_"
    Usage:
    hide.exe <n> <filenames for h> <filenames for o>

    Thus, the prefixed symbols become hidden in the sense that they now have a
    special prefix.
 */

 using namespace std;

 void stop(char *errorMsg) {
   printf("%s\n", errorMsg);
   exit(1);
 }

 // an entry in the symbol table of a .OBJ file
 class Symbol {
 public:
   __int64 name;
   unsigned value;
   unsigned short sectionNum, type;
   char storageClass, nAux;
 };

 class _rstream : public istrstream {
 private:
   const char *buf;

 protected:
   _rstream(pair<const char *, streamsize> p)
       : istrstream(p.first, p.second), buf(p.first) {}
   ~_rstream() { delete[] buf; }
 };

 // A stream encapuslating the content of a file or the content of a string,
 // overriding the >> operator to read various integer types in binary form,
 // as well as a symbol table entry.
 class rstream : public _rstream {
 private:
   template <class T> inline rstream &doRead(T &x) {
     read((char *)&x, sizeof(T));
     return *this;
   }
   static pair<const char *, streamsize> getBuf(const char *fileName) {
     ifstream raw(fileName, ios::binary | ios::in);
     if (!raw.is_open())
       stop("rstream.getBuf: Error opening file");
     raw.seekg(0, ios::end);
     streampos fileSize = raw.tellg();
     if (fileSize < 0)
       stop("rstream.getBuf: Error reading file");
     char *buf = new char[fileSize];
     raw.seekg(0, ios::beg);
     raw.read(buf, fileSize);
     return pair<const char *, streamsize>(buf, fileSize);
   }

 public:
   // construct from a string
   rstream(const char *buf, streamsize size)
       : _rstream(pair<const char *, streamsize>(buf, size)) {}
   // construct from a file whole content is fully read once to initialize the
   // content of this stream
   rstream(const char *fileName) : _rstream(getBuf(fileName)) {}
   rstream &operator>>(int &x) { return doRead(x); }
   rstream &operator>>(unsigned &x) { return doRead(x); }
   rstream &operator>>(short &x) { return doRead(x); }
   rstream &operator>>(unsigned short &x) { return doRead(x); }
   rstream &operator>>(Symbol &e) {
     read((char *)&e, 18);
     return *this;
   }
 };

 // string table in a .OBJ file
 class StringTable {
 private:
   map<string, unsigned> directory;
   size_t length;
   char *data;

   // make <directory> from <length> bytes in <data>
   void makeDirectory(void) {
     unsigned i = 4;
     while (i < length) {
       string s = string(data + i);
       directory.insert(make_pair(s, i));
       i += s.size() + 1;
     }
   }
   // initialize <length> and <data> with contents specified by the arguments
   void init(const char *_data) {
     unsigned _length = *(unsigned *)_data;

     if (_length < sizeof(unsigned) || _length != *(unsigned *)_data)
       stop("StringTable.init: Invalid symbol table");
     if (_data[_length - 1]) {
       // to prevent runaway strings, make sure the data ends with a zero
       data = new char[length = _length + 1];
       data[_length] = 0;
     } else {
       data = new char[length = _length];
     }
     *(unsigned *)data = length;
     KMP_MEMCPY(data + sizeof(unsigned), _data + sizeof(unsigned),
                length - sizeof(unsigned));
     makeDirectory();
   }

 public:
   StringTable(rstream &f) {
     // Construct string table by reading from f.
     streampos s;
     unsigned strSize;
     char *strData;

     s = f.tellg();
     f >> strSize;
     if (strSize < sizeof(unsigned))
       stop("StringTable: Invalid string table");
     strData = new char[strSize];
     *(unsigned *)strData = strSize;
     // read the raw data into <strData>
     f.read(strData + sizeof(unsigned), strSize - sizeof(unsigned));
     s = f.tellg() - s;
     if (s < strSize)
       stop("StringTable: Unexpected EOF");
     init(strData);
     delete[] strData;
   }
   StringTable(const set<string> &strings) {
     // Construct string table from given strings.
     char *p;
     set<string>::const_iterator it;
     size_t s;

     // count required size for data
     for (length = sizeof(unsigned), it = strings.begin(); it != strings.end();
          ++it) {
       size_t l = (*it).size();

       if (l > (unsigned)0xFFFFFFFF)
         stop("StringTable: String too long");
       if (l > 8) {
         length += l + 1;
         if (length > (unsigned)0xFFFFFFFF)
           stop("StringTable: Symbol table too long");
       }
     }
     data = new char[length];
     *(unsigned *)data = length;
     // populate data and directory
     for (p = data + sizeof(unsigned), it = strings.begin(); it != strings.end();
          ++it) {
       const string &str = *it;
       size_t l = str.size();
       if (l > 8) {
         directory.insert(make_pair(str, p - data));
         KMP_MEMCPY(p, str.c_str(), l);
         p[l] = 0;
         p += l + 1;
       }
     }
   }
   ~StringTable() { delete[] data; }
   // Returns encoding for given string based on this string table. Error if
   // string length is greater than 8 but string is not in the string table
   // -- returns 0.
   __int64 encode(const string &str) {
     __int64 r;

     if (str.size() <= 8) {
       // encoded directly
       ((char *)&r)[7] = 0;
       KMP_STRNCPY_S((char *)&r, sizeof(r), str.c_str(), 8);
       return r;
     } else {
       // represented as index into table
       map<string, unsigned>::const_iterator it = directory.find(str);
       if (it == directory.end())
         stop("StringTable::encode: String now found in string table");
       ((unsigned *)&r)[0] = 0;
       ((unsigned *)&r)[1] = (*it).second;
       return r;
     }
   }
   // Returns string represented by x based on this string table. Error if x
   // references an invalid position in the table--returns the empty string.
   string decode(__int64 x) const {
     if (*(unsigned *)&x == 0) {
       // represented as index into table
       unsigned &p = ((unsigned *)&x)[1];
       if (p >= length)
         stop("StringTable::decode: Invalid string table lookup");
       return string(data + p);
     } else {
       // encoded directly
       char *p = (char *)&x;
       int i;

       for (i = 0; i < 8 && p[i]; ++i)
         ;
       return string(p, i);
     }
   }
   void write(ostream &os) { os.write(data, length); }
 };

 // for the named object file, determines the set of defined symbols and the set
 // of undefined external symbols and writes them to <defined> and <undefined>
 // respectively
 void computeExternalSymbols(const char *fileName, set<string> *defined,
                             set<string> *undefined) {
   streampos fileSize;
   size_t strTabStart;
   unsigned symTabStart, symNEntries;
   rstream f(fileName);

   f.seekg(0, ios::end);
   fileSize = f.tellg();

   f.seekg(8);
   f >> symTabStart >> symNEntries;
   // seek to the string table
   f.seekg(strTabStart = symTabStart + 18 * (size_t)symNEntries);
   if (f.eof()) {
     printf("computeExternalSymbols: fileName='%s', fileSize = %lu, symTabStart "
            "= %u, symNEntries = %u\n",
            fileName, (unsigned long)fileSize, symTabStart, symNEntries);
     stop("computeExternalSymbols: Unexpected EOF 1");
   }
   StringTable stringTable(f); // read the string table
   if (f.tellg() != fileSize)
     stop("computeExternalSymbols: Unexpected data after string table");

   f.clear();
   f.seekg(symTabStart); // seek to the symbol table

   defined->clear();
   undefined->clear();
   for (int i = 0; i < symNEntries; ++i) {
     // process each entry
     Symbol e;

     if (f.eof())
       stop("computeExternalSymbols: Unexpected EOF 2");
     f >> e;
     if (f.fail())
       stop("computeExternalSymbols: File read error");
     if (e.nAux) { // auxiliary entry: skip
       f.seekg(e.nAux * 18, ios::cur);
       i += e.nAux;
     }
     // if symbol is extern and defined in the current file, insert it
     if (e.storageClass == 2)
       if (e.sectionNum)
         defined->insert(stringTable.decode(e.name));
       else
         undefined->insert(stringTable.decode(e.name));
   }
 }

 // For each occurrence of an external symbol in the object file named by
 // by <fileName> that is a member of <hide>, renames it by prefixing
 // with "__kmp_external_", writing back the file in-place
 void hideSymbols(char *fileName, const set<string> &hide) {
   static const string prefix("__kmp_external_");
   set<string> strings; // set of all occurring symbols, appropriately prefixed
   streampos fileSize;
   size_t strTabStart;
   unsigned symTabStart, symNEntries;
   int i;
   rstream in(fileName);

   in.seekg(0, ios::end);
   fileSize = in.tellg();

   in.seekg(8);
   in >> symTabStart >> symNEntries;
   in.seekg(strTabStart = symTabStart + 18 * (size_t)symNEntries);
   if (in.eof())
     stop("hideSymbols: Unexpected EOF");
   StringTable stringTableOld(in); // read original string table

   if (in.tellg() != fileSize)
     stop("hideSymbols: Unexpected data after string table");

   // compute set of occurring strings with prefix added
   for (i = 0; i < symNEntries; ++i) {
     Symbol e;

     in.seekg(symTabStart + i * 18);
     if (in.eof())
       stop("hideSymbols: Unexpected EOF");
     in >> e;
     if (in.fail())
       stop("hideSymbols: File read error");
     if (e.nAux)
       i += e.nAux;
     const string &s = stringTableOld.decode(e.name);
     // if symbol is extern and found in <hide>, prefix and insert into strings,
     // otherwise, just insert into strings without prefix
     strings.insert(
         (e.storageClass == 2 && hide.find(s) != hide.end()) ? prefix + s : s);
   }

   ofstream out(fileName, ios::trunc | ios::out | ios::binary);
   if (!out.is_open())
     stop("hideSymbols: Error opening output file");

   // make new string table from string set
   StringTable stringTableNew = StringTable(strings);

   // copy input file to output file up to just before the symbol table
   in.seekg(0);
   char *buf = new char[symTabStart];
   in.read(buf, symTabStart);
   out.write(buf, symTabStart);
   delete[] buf;

   // copy input symbol table to output symbol table with name translation
   for (i = 0; i < symNEntries; ++i) {
     Symbol e;

     in.seekg(symTabStart + i * 18);
     if (in.eof())
       stop("hideSymbols: Unexpected EOF");
     in >> e;
     if (in.fail())
       stop("hideSymbols: File read error");
     const string &s = stringTableOld.decode(e.name);
     out.seekp(symTabStart + i * 18);
     e.name = stringTableNew.encode(
         (e.storageClass == 2 && hide.find(s) != hide.end()) ? prefix + s : s);
     out.write((char *)&e, 18);
     if (out.fail())
       stop("hideSymbols: File write error");
     if (e.nAux) {
       // copy auxiliary symbol table entries
       int nAux = e.nAux;
       for (int j = 1; j <= nAux; ++j) {
         in >> e;
         out.seekp(symTabStart + (i + j) * 18);
         out.write((char *)&e, 18);
       }
       i += nAux;
     }
   }
   // output string table
   stringTableNew.write(out);
 }

 // returns true iff <a> and <b> have no common element
 template <class T> bool isDisjoint(const set<T> &a, const set<T> &b) {
   set<T>::const_iterator ita, itb;

   for (ita = a.begin(), itb = b.begin(); ita != a.end() && itb != b.end();) {
     const T &ta = *ita, &tb = *itb;
     if (ta < tb)
       ++ita;
     else if (tb < ta)
       ++itb;
     else
       return false;
   }
   return true;
 }

 // PRE: <defined> and <undefined> are arrays with <nTotal> elements where
 // <nTotal> >= <nExternal>.  The first <nExternal> elements correspond to the
 // external object files and the rest correspond to the internal object files.
 // POST: file x is said to depend on file y if undefined[x] and defined[y] are
 // not disjoint. Returns the transitive closure of the set of internal object
 // files, as a set of file indexes, under the 'depends on' relation, minus the
 // set of internal object files.
 set<int> *findRequiredExternal(int nExternal, int nTotal, set<string> *defined,
                                set<string> *undefined) {
   set<int> *required = new set<int>;
   set<int> fresh[2];
   int i, cur = 0;
   bool changed;

   for (i = nTotal - 1; i >= nExternal; --i)
     fresh[cur].insert(i);
   do {
     changed = false;
     for (set<int>::iterator it = fresh[cur].begin(); it != fresh[cur].end();
          ++it) {
       set<string> &s = undefined[*it];

       for (i = 0; i < nExternal; ++i) {
         if (required->find(i) == required->end()) {
           if (!isDisjoint(defined[i], s)) {
             // found a new qualifying element
             required->insert(i);
             fresh[1 - cur].insert(i);
             changed = true;
           }
         }
       }
     }
     fresh[cur].clear();
     cur = 1 - cur;
   } while (changed);
   return required;
 }

 int main(int argc, char **argv) {
   int nExternal, nInternal, i;
   set<string> *defined, *undefined;
   set<int>::iterator it;

   if (argc < 3)
     stop("Please specify a positive integer followed by a list of object "
          "filenames");
   nExternal = atoi(argv[1]);
   if (nExternal <= 0)
     stop("Please specify a positive integer followed by a list of object "
          "filenames");
   if (nExternal + 2 > argc)
     stop("Too few external objects");
   nInternal = argc - nExternal - 2;
   defined = new set<string>[argc - 2];
   undefined = new set<string>[argc - 2];

   // determine the set of defined and undefined external symbols
   for (i = 2; i < argc; ++i)
     computeExternalSymbols(argv[i], defined + i - 2, undefined + i - 2);

   // determine the set of required external files
   set<int> *requiredExternal =
       findRequiredExternal(nExternal, argc - 2, defined, undefined);
   set<string> hide;

   // determine the set of symbols to hide--namely defined external symbols of
   // the required external files
   for (it = requiredExternal->begin(); it != requiredExternal->end(); ++it) {
     int idx = *it;
     set<string>::iterator it2;
     // We have to insert one element at a time instead of inserting a range
     // because the insert member function taking a range doesn't exist on
     // Windows* OS, at least at the time of this writing.
     for (it2 = defined[idx].begin(); it2 != defined[idx].end(); ++it2)
       hide.insert(*it2);
   }

   // process the external files--removing those that are not required and hiding
   //   the appropriate symbols in the others
   for (i = 0; i < nExternal; ++i)
     if (requiredExternal->find(i) != requiredExternal->end())
       hideSymbols(argv[2 + i], hide);
     else
       remove(argv[2 + i]);
   // hide the appropriate symbols in the internal files
   for (i = nExternal + 2; i < argc; ++i)
     hideSymbols(argv[i], hide);
   return 0;
 }
	/*
	* extractExternal.cpp
	*/


	//===----------------------------------------------------------------------===//
	//
	// The LLVM Compiler Infrastructure
	//
	// This file is dual licensed under the MIT and the University of Illinois Open
	// Source Licenses. See LICENSE.txt for details.
	//
	//===----------------------------------------------------------------------===//


	#include <fstream>
	#include <iostream>
	#include <map>
	#include <set>
	#include <stdlib.h>
	#include <string>
	#include <strstream>

	/* Given a set of n object files h ('external' object files) and a set of m
	object files o ('internal' object files),
	1. Determines r, the subset of h that o depends on, directly or indirectly
	2. Removes the files in h - r from the file system
	3. For each external symbol defined in some file in r, rename it in r U o
	by prefixing it with "__kmp_external_"
	Usage:
	hide.exe <n> <filenames for h> <filenames for o>

	Thus, the prefixed symbols become hidden in the sense that they now have a
	special prefix.
	*/

	using namespace std;

	void stop(char *errorMsg) {
	printf("%s\n", errorMsg);
	exit(1);
	}

	// an entry in the symbol table of a .OBJ file
	class Symbol {
	public:
	__int64 name;
	unsigned value;
	unsigned short sectionNum, type;
	char storageClass, nAux;
	};

	class _rstream : public istrstream {
	private:
	const char *buf;

	protected:
	_rstream(pair<const char *, streamsize> p)
	: istrstream(p.first, p.second), buf(p.first) {}
	~_rstream() { delete[] buf; }
	};

	// A stream encapuslating the content of a file or the content of a string,
	// overriding the >> operator to read various integer types in binary form,
	// as well as a symbol table entry.
	class rstream : public _rstream {
	private:
	template <class T> inline rstream &doRead(T &x) {
	read((char *)&x, sizeof(T));
	return *this;
	}
	static pair<const char , streamsize> getBuf(const char fileName) {
	ifstream raw(fileName, ios::binary \| ios::in);
	if (!raw.is_open())
	stop("rstream.getBuf: Error opening file");
	raw.seekg(0, ios::end);
	streampos fileSize = raw.tellg();
	if (fileSize < 0)
	stop("rstream.getBuf: Error reading file");
	char *buf = new char[fileSize];
	raw.seekg(0, ios::beg);
	raw.read(buf, fileSize);
	return pair<const char *, streamsize>(buf, fileSize);
	}

	public:
	// construct from a string
	rstream(const char *buf, streamsize size)
	: _rstream(pair<const char *, streamsize>(buf, size)) {}
	// construct from a file whole content is fully read once to initialize the
	// content of this stream
	rstream(const char *fileName) : _rstream(getBuf(fileName)) {}
	rstream &operator>>(int &x) { return doRead(x); }
	rstream &operator>>(unsigned &x) { return doRead(x); }
	rstream &operator>>(short &x) { return doRead(x); }
	rstream &operator>>(unsigned short &x) { return doRead(x); }
	rstream &operator>>(Symbol &e) {
	read((char *)&e, 18);
	return *this;
	}
	};

	// string table in a .OBJ file
	class StringTable {
	private:
	map<string, unsigned> directory;
	size_t length;
	char *data;

	// make <directory> from <length> bytes in <data>
	void makeDirectory(void) {
	unsigned i = 4;
	while (i < length) {
	string s = string(data + i);
	directory.insert(make_pair(s, i));
	i += s.size() + 1;
	}
	}
	// initialize <length> and <data> with contents specified by the arguments
	void init(const char *_data) {
	unsigned _length = (unsigned )_data;

	if (_length < sizeof(unsigned) \|\| _length != (unsigned )_data)
	stop("StringTable.init: Invalid symbol table");
	if (_data[_length - 1]) {
	// to prevent runaway strings, make sure the data ends with a zero
	data = new char[length = _length + 1];
	data[_length] = 0;
	} else {
	data = new char[length = _length];
	}
	(unsigned )data = length;
	KMP_MEMCPY(data + sizeof(unsigned), _data + sizeof(unsigned),
	length - sizeof(unsigned));
	makeDirectory();
	}

	public:
	StringTable(rstream &f) {
	// Construct string table by reading from f.
	streampos s;
	unsigned strSize;
	char *strData;

	s = f.tellg();
	f >> strSize;
	if (strSize < sizeof(unsigned))
	stop("StringTable: Invalid string table");
	strData = new char[strSize];
	(unsigned )strData = strSize;
	// read the raw data into <strData>
	f.read(strData + sizeof(unsigned), strSize - sizeof(unsigned));
	s = f.tellg() - s;
	if (s < strSize)
	stop("StringTable: Unexpected EOF");
	init(strData);
	delete[] strData;
	}
	StringTable(const set<string> &strings) {
	// Construct string table from given strings.
	char *p;
	set<string>::const_iterator it;
	size_t s;

	// count required size for data
	for (length = sizeof(unsigned), it = strings.begin(); it != strings.end();
	++it) {
	size_t l = (*it).size();

	if (l > (unsigned)0xFFFFFFFF)
	stop("StringTable: String too long");
	if (l > 8) {
	length += l + 1;
	if (length > (unsigned)0xFFFFFFFF)
	stop("StringTable: Symbol table too long");
	}
	}
	data = new char[length];
	(unsigned )data = length;
	// populate data and directory
	for (p = data + sizeof(unsigned), it = strings.begin(); it != strings.end();
	++it) {
	const string &str = *it;
	size_t l = str.size();
	if (l > 8) {
	directory.insert(make_pair(str, p - data));
	KMP_MEMCPY(p, str.c_str(), l);
	p[l] = 0;
	p += l + 1;
	}
	}
	}
	~StringTable() { delete[] data; }
	// Returns encoding for given string based on this string table. Error if
	// string length is greater than 8 but string is not in the string table
	// -- returns 0.
	__int64 encode(const string &str) {
	__int64 r;

	if (str.size() <= 8) {
	// encoded directly
	((char *)&r)[7] = 0;
	KMP_STRNCPY_S((char *)&r, sizeof(r), str.c_str(), 8);
	return r;
	} else {
	// represented as index into table
	map<string, unsigned>::const_iterator it = directory.find(str);
	if (it == directory.end())
	stop("StringTable::encode: String now found in string table");
	((unsigned *)&r)[0] = 0;
	((unsigned )&r)[1] = (it).second;
	return r;
	}
	}
	// Returns string represented by x based on this string table. Error if x
	// references an invalid position in the table--returns the empty string.
	string decode(__int64 x) const {
	if ((unsigned )&x == 0) {
	// represented as index into table
	unsigned &p = ((unsigned *)&x)[1];
	if (p >= length)
	stop("StringTable::decode: Invalid string table lookup");
	return string(data + p);
	} else {
	// encoded directly
	char p = (char )&x;
	int i;

	for (i = 0; i < 8 && p[i]; ++i)
	;
	return string(p, i);
	}
	}
	void write(ostream &os) { os.write(data, length); }
	};

	// for the named object file, determines the set of defined symbols and the set
	// of undefined external symbols and writes them to <defined> and <undefined>
	// respectively
	void computeExternalSymbols(const char fileName, set<string> defined,
	set<string> *undefined) {
	streampos fileSize;
	size_t strTabStart;
	unsigned symTabStart, symNEntries;
	rstream f(fileName);

	f.seekg(0, ios::end);
	fileSize = f.tellg();

	f.seekg(8);
	f >> symTabStart >> symNEntries;
	// seek to the string table
	f.seekg(strTabStart = symTabStart + 18 * (size_t)symNEntries);
	if (f.eof()) {
	printf("computeExternalSymbols: fileName='%s', fileSize = %lu, symTabStart "
	"= %u, symNEntries = %u\n",
	fileName, (unsigned long)fileSize, symTabStart, symNEntries);
	stop("computeExternalSymbols: Unexpected EOF 1");
	}
	StringTable stringTable(f); // read the string table
	if (f.tellg() != fileSize)
	stop("computeExternalSymbols: Unexpected data after string table");

	f.clear();
	f.seekg(symTabStart); // seek to the symbol table

	defined->clear();
	undefined->clear();
	for (int i = 0; i < symNEntries; ++i) {
	// process each entry
	Symbol e;

	if (f.eof())
	stop("computeExternalSymbols: Unexpected EOF 2");
	f >> e;
	if (f.fail())
	stop("computeExternalSymbols: File read error");
	if (e.nAux) { // auxiliary entry: skip
	f.seekg(e.nAux * 18, ios::cur);
	i += e.nAux;
	}
	// if symbol is extern and defined in the current file, insert it
	if (e.storageClass == 2)
	if (e.sectionNum)
	defined->insert(stringTable.decode(e.name));
	else
	undefined->insert(stringTable.decode(e.name));
	}
	}

	// For each occurrence of an external symbol in the object file named by
	// by <fileName> that is a member of <hide>, renames it by prefixing
	// with "__kmp_external_", writing back the file in-place
	void hideSymbols(char *fileName, const set<string> &hide) {
	static const string prefix("__kmp_external_");
	set<string> strings; // set of all occurring symbols, appropriately prefixed
	streampos fileSize;
	size_t strTabStart;
	unsigned symTabStart, symNEntries;
	int i;
	rstream in(fileName);

	in.seekg(0, ios::end);
	fileSize = in.tellg();

	in.seekg(8);
	in >> symTabStart >> symNEntries;
	in.seekg(strTabStart = symTabStart + 18 * (size_t)symNEntries);
	if (in.eof())
	stop("hideSymbols: Unexpected EOF");
	StringTable stringTableOld(in); // read original string table

	if (in.tellg() != fileSize)
	stop("hideSymbols: Unexpected data after string table");

	// compute set of occurring strings with prefix added
	for (i = 0; i < symNEntries; ++i) {
	Symbol e;

	in.seekg(symTabStart + i * 18);
	if (in.eof())
	stop("hideSymbols: Unexpected EOF");
	in >> e;
	if (in.fail())
	stop("hideSymbols: File read error");
	if (e.nAux)
	i += e.nAux;
	const string &s = stringTableOld.decode(e.name);
	// if symbol is extern and found in <hide>, prefix and insert into strings,
	// otherwise, just insert into strings without prefix
	strings.insert(
	(e.storageClass == 2 && hide.find(s) != hide.end()) ? prefix + s : s);
	}

	ofstream out(fileName, ios::trunc \| ios::out \| ios::binary);
	if (!out.is_open())
	stop("hideSymbols: Error opening output file");

	// make new string table from string set
	StringTable stringTableNew = StringTable(strings);

	// copy input file to output file up to just before the symbol table
	in.seekg(0);
	char *buf = new char[symTabStart];
	in.read(buf, symTabStart);
	out.write(buf, symTabStart);
	delete[] buf;

	// copy input symbol table to output symbol table with name translation
	for (i = 0; i < symNEntries; ++i) {
	Symbol e;

	in.seekg(symTabStart + i * 18);
	if (in.eof())
	stop("hideSymbols: Unexpected EOF");
	in >> e;
	if (in.fail())
	stop("hideSymbols: File read error");
	const string &s = stringTableOld.decode(e.name);
	out.seekp(symTabStart + i * 18);
	e.name = stringTableNew.encode(
	(e.storageClass == 2 && hide.find(s) != hide.end()) ? prefix + s : s);
	out.write((char *)&e, 18);
	if (out.fail())
	stop("hideSymbols: File write error");
	if (e.nAux) {
	// copy auxiliary symbol table entries
	int nAux = e.nAux;
	for (int j = 1; j <= nAux; ++j) {
	in >> e;
	out.seekp(symTabStart + (i + j) * 18);
	out.write((char *)&e, 18);
	}
	i += nAux;
	}
	}
	// output string table
	stringTableNew.write(out);
	}

	// returns true iff <a> and <b> have no common element
	template <class T> bool isDisjoint(const set<T> &a, const set<T> &b) {
	set<T>::const_iterator ita, itb;

	for (ita = a.begin(), itb = b.begin(); ita != a.end() && itb != b.end();) {
	const T &ta = ita, &tb = itb;
	if (ta < tb)
	++ita;
	else if (tb < ta)
	++itb;
	else
	return false;
	}
	return true;
	}

	// PRE: <defined> and <undefined> are arrays with <nTotal> elements where
	// <nTotal> >= <nExternal>. The first <nExternal> elements correspond to the
	// external object files and the rest correspond to the internal object files.
	// POST: file x is said to depend on file y if undefined[x] and defined[y] are
	// not disjoint. Returns the transitive closure of the set of internal object
	// files, as a set of file indexes, under the 'depends on' relation, minus the
	// set of internal object files.
	set<int> findRequiredExternal(int nExternal, int nTotal, set<string> defined,
	set<string> *undefined) {
	set<int> *required = new set<int>;
	set<int> fresh[2];
	int i, cur = 0;
	bool changed;

	for (i = nTotal - 1; i >= nExternal; --i)
	fresh[cur].insert(i);
	do {
	changed = false;
	for (set<int>::iterator it = fresh[cur].begin(); it != fresh[cur].end();
	++it) {
	set<string> &s = undefined[*it];

	for (i = 0; i < nExternal; ++i) {
	if (required->find(i) == required->end()) {
	if (!isDisjoint(defined[i], s)) {
	// found a new qualifying element
	required->insert(i);
	fresh[1 - cur].insert(i);
	changed = true;
	}
	}
	}
	}
	fresh[cur].clear();
	cur = 1 - cur;
	} while (changed);
	return required;
	}

	int main(int argc, char **argv) {
	int nExternal, nInternal, i;
	set<string> defined, undefined;
	set<int>::iterator it;

	if (argc < 3)
	stop("Please specify a positive integer followed by a list of object "
	"filenames");
	nExternal = atoi(argv[1]);
	if (nExternal <= 0)
	stop("Please specify a positive integer followed by a list of object "
	"filenames");
	if (nExternal + 2 > argc)
	stop("Too few external objects");
	nInternal = argc - nExternal - 2;
	defined = new set<string>[argc - 2];
	undefined = new set<string>[argc - 2];

	// determine the set of defined and undefined external symbols
	for (i = 2; i < argc; ++i)
	computeExternalSymbols(argv[i], defined + i - 2, undefined + i - 2);

	// determine the set of required external files
	set<int> *requiredExternal =
	findRequiredExternal(nExternal, argc - 2, defined, undefined);
	set<string> hide;

	// determine the set of symbols to hide--namely defined external symbols of
	// the required external files
	for (it = requiredExternal->begin(); it != requiredExternal->end(); ++it) {
	int idx = *it;
	set<string>::iterator it2;
	// We have to insert one element at a time instead of inserting a range
	// because the insert member function taking a range doesn't exist on
	// Windows* OS, at least at the time of this writing.
	for (it2 = defined[idx].begin(); it2 != defined[idx].end(); ++it2)
	hide.insert(*it2);
	}

	// process the external files--removing those that are not required and hiding
	// the appropriate symbols in the others
	for (i = 0; i < nExternal; ++i)
	if (requiredExternal->find(i) != requiredExternal->end())
	hideSymbols(argv[2 + i], hide);
	else
	remove(argv[2 + i]);
	// hide the appropriate symbols in the internal files
	for (i = nExternal + 2; i < argc; ++i)
	hideSymbols(argv[i], hide);
	return 0;
	}