src/systemc/tests/tlm/endian_conv/test_endian_conv.cpp - public/gem5 - Git at Google

 /*****************************************************************************

   Licensed to Accellera Systems Initiative Inc. (Accellera) under one or
   more contributor license agreements.  See the NOTICE file distributed
   with this work for additional information regarding copyright ownership.
   Accellera licenses this file to you under the Apache License, Version 2.0
   (the "License"); you may not use this file except in compliance with the
   License.  You may obtain a copy of the License at

     http://www.apache.org/licenses/LICENSE-2.0

   Unless required by applicable law or agreed to in writing, software
   distributed under the License is distributed on an "AS IS" BASIS,
   WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
   implied.  See the License for the specific language governing
   permissions and limitations under the License.

  *****************************************************************************/


 /*
 This C++ programme runs single transactions through a single
 endianness conversion function, then through a simple memory model,
 then converts it back.
 Takes the initial memory state as input and provides the final
 memory state as output.
 */


 #define BUFFER_SIZE 2048

 #include<systemc>
 #include "tlm.h"
 #include<iostream>
 #include<time.h>
 #include <fstream>

 using namespace std;
 using namespace tlm;
 using namespace sc_dt;


 // simple set of types with known sizeof(), for testing //
 template<int SIZE> class dt {
   char content[SIZE];
 };


 #define convert(function) \
   switch(data_width) { \
     case 1:  function<dt<1> >(&txn,bus_width); break; \
     case 2:  function<dt<2> >(&txn,bus_width); break; \
     case 4:  function<dt<4> >(&txn,bus_width); break; \
     case 8:  function<dt<8> >(&txn,bus_width); break; \
     case 16:  function<dt<16> >(&txn,bus_width); break; \
     case 32:  function<dt<32> >(&txn,bus_width); break; \
     default:  cout << "bad data width\n"; \
     exit(1); \
   }


 // forward declarations - see below
 template<class DATAWORD> inline void
 local_single_tohe(tlm_generic_payload *txn, unsigned int sizeof_databus);
 template<class DATAWORD> inline void
 local_single_fromhe(tlm_generic_payload *txn, unsigned int sizeof_databus);


 void test_a_conversion(char cmd, tlm_generic_payload &txn, std::ifstream & fin) {

   if(cmd == 'R') txn.set_read();
   else txn.set_write();

   fin.ignore(10000,'=');
   uint64 a;
   fin >> a;
   txn.set_address(a);

   fin.ignore(10000,'=');
   int l;
   fin >> l;
   txn.set_data_length(l);

   int bus_width;
   fin.ignore(10000,'=');  fin >> bus_width;

   int data_width;
   fin.ignore(10000,'=');  fin >> data_width;

   int initiator_offset;
   fin.ignore(10000,'=');  fin >> initiator_offset;

   unsigned char *original_byte_enable = 0;
   unsigned char *byte_enable_legible =
     new unsigned char[txn.get_data_length() + 1];
   memset(byte_enable_legible, 0, txn.get_data_length() + 1);
   fin.ignore(10000,'=');
   for(unsigned b=0; b<txn.get_data_length(); b++) {
     char tmp; fin >> tmp;
     if((tmp=='0')||(tmp=='1')||(tmp=='x')) byte_enable_legible[b]=tmp;
     else break;
   }
   if((byte_enable_legible[0] == '1') || (byte_enable_legible[0] == '0')) {
     txn.set_byte_enable_ptr(new unsigned char[txn.get_data_length()]);
     txn.set_byte_enable_length(txn.get_data_length());
     original_byte_enable = txn.get_byte_enable_ptr();
     for(unsigned int i=0; i<txn.get_data_length(); i++) {
       if(byte_enable_legible[i] == '0') {
         txn.get_byte_enable_ptr()[i] = TLM_BYTE_DISABLED;
       } else if(byte_enable_legible[i] == '1') {
         txn.get_byte_enable_ptr()[i] = TLM_BYTE_ENABLED;
       } else {
         // not enough byte enables
         txn.set_byte_enable_length(i);
         break;
       }
     }
   } else {
     txn.set_byte_enable_ptr(0);
     txn.set_byte_enable_length(0);
   }

   int stream_width;
   fin.ignore(10000,'=');  fin >> stream_width;
   txn.set_streaming_width(stream_width);

   cout << "enter initiator memory state = ("<< BUFFER_SIZE << " characters)\n";
   unsigned char initiator_mem[BUFFER_SIZE+1];
   memset(initiator_mem, 0, BUFFER_SIZE+1);
   fin.ignore(10000,'=');  fin >> initiator_mem;

   txn.set_data_ptr(initiator_mem + initiator_offset);

   cout << "enter target memory state = ("<< BUFFER_SIZE << " characters)\n";
   unsigned char target_mem[BUFFER_SIZE+1];
   memset(target_mem, 0, BUFFER_SIZE+1);
   fin.ignore(10000,'=');  fin >> target_mem;

   cout << "enter converter choice = (0 => generic, 1 => word, 2 => aligned, 3 => single)\n";
   int converter;
   fin.ignore(10000,'=');  fin >> converter;

   cout << "Initiator Intent\n";
   cout << "  Cmd = " << cmd << endl;
   cout << "  Addr = " << txn.get_address() << endl;
   cout << "  Len = " << txn.get_data_length() << endl;
   cout << "  Bus Width = " << bus_width << endl;
   cout << "  Data Word = " << data_width << endl;
 #ifdef VERBOSE
   cout << "  Initiator offset and txn data pointer = " << initiator_offset << ", " << int(txn.get_data_ptr()) << endl;
   cout << "  Byte enables and byte enable pointer = " << byte_enable_legible << ", " << int(txn.get_byte_enable_ptr()) << endl;
 #else
   cout << "  Initiator offset = " << initiator_offset << endl;
   cout << "  Byte enables = " << byte_enable_legible << endl;
 #endif
   cout << "  Byte enable length = " << txn.get_byte_enable_length() << endl;
   cout << "  Streaming width = " << txn.get_streaming_width() << endl;
   cout << "  Initiator memory = " << initiator_mem << endl;
   cout << "  Target memory = " << target_mem << endl;
   cout << "  Converter = " << converter << endl << endl;

   // initiator //
   switch(converter) {
     case 0:  convert(tlm_to_hostendian_generic); break;
     case 1:  convert(tlm_to_hostendian_word); break;
     case 2:  convert(tlm_to_hostendian_aligned); break;
     case 3:  convert(tlm_to_hostendian_single); break;
     case 4:  convert(local_single_tohe); break;
     default:  cout << "no such converter as " << converter << endl;
     exit(1);
   }

   cout << "Converted Transaction\n";
   cout << "  Addr = " << txn.get_address() << endl;
   cout << "  Len = " << txn.get_data_length() << endl;
 #ifdef VERBOSE
   cout << "  Txn data pointer = " << int(txn.get_data_ptr()) << endl;
   if(txn.get_byte_enable_ptr() != 0) {
     cout << "  Byte enables and byte enable pointer = ";
     for(unsigned int i=0; i<txn.get_data_length(); i++)
       cout << (txn.get_byte_enable_ptr()[i] ? '1' : '0');
     cout << ", " << int(txn.get_byte_enable_ptr()) << endl;
   }
 #else
   cout << "  Txn data pointer = " <<
     (txn.get_data_ptr() == initiator_mem+initiator_offset ? "unchanged" : "changed") << endl;
   if(txn.get_byte_enable_ptr() != 0) {
     cout << "  Byte enables and byte enable pointer = ";
     for(unsigned int i=0; i<txn.get_data_length(); i++)
       cout << (txn.get_byte_enable_ptr()[i] ? '1' : '0');
     cout << ", " <<
      (txn.get_byte_enable_ptr() == original_byte_enable ? "unchanged" : "changed") << endl;
   }
 #endif
   cout << "  Byte enable length = " << txn.get_byte_enable_length() << endl;
   cout << "  Streaming width = " << txn.get_streaming_width() << endl;
   cout << endl;

   // target //
   int sw = txn.get_streaming_width();
   if((txn.get_data_length()/sw)*sw != txn.get_data_length()) {
     cout << "ERROR: Data length not a multiple of streaming width\n";
     exit(1);
   }
   for(unsigned int ss = 0; ss < txn.get_data_length(); ss += sw) {
     if(txn.get_byte_enable_ptr() == 0) {
       // simple transaction can be processed by mem-copy
       if(txn.is_read())
         memcpy(ss+txn.get_data_ptr(), target_mem+txn.get_address(), sw);
       else
         memcpy(target_mem+txn.get_address(), ss+txn.get_data_ptr(), sw);
     } else {
       // complex transaction, byte enables, maybe shorter than data
       int bel = txn.get_byte_enable_length();
       if(txn.is_read()) {
         for(int j=0; j<sw; j++) {
           if(txn.get_byte_enable_ptr()[(ss+j) % bel])
             (txn.get_data_ptr())[ss+j] = target_mem[j+txn.get_address()];
         }
       } else {
         for(int j=0; j<sw; j++) {
           if(txn.get_byte_enable_ptr()[(ss+j) % bel])
             target_mem[j+txn.get_address()] = (txn.get_data_ptr())[ss+j];
         }
       }
     }
   }

   // initiator again //
   if((rand() & 0x100) && (converter < 4)) {
 #ifdef VERBOSE
     cout << "using single entry point for response\n";
 #endif
     tlm_from_hostendian(&txn);
   } else {
 #ifdef VERBOSE
     cout << "using specific entry point for response\n";
 #endif
     switch(converter) {
       case 0:  convert(tlm_from_hostendian_generic); break;
       case 1:  convert(tlm_from_hostendian_word); break;
       case 2:  convert(tlm_from_hostendian_aligned); break;
       case 3:  convert(tlm_from_hostendian_single); break;
       case 4:  convert(local_single_fromhe); break;
       default:  cout << "no such converter as " << converter << endl;
       exit(1);
     }
   }

   // print the results //
   cout << "Memory States after Transaction\n";
   cout << "  initiator = " << initiator_mem << endl;
   cout << "  target = " << target_mem << endl << endl;

   // clean up
   delete [] byte_enable_legible;
   if(original_byte_enable != 0) delete [] original_byte_enable;
 }


 void pool_status() {
   cout << "Pool status: ";
   tlm_endian_context *f = global_tlm_endian_context_pool.first;
   while(f!=0) {
     cout << "(" << f->dbuf_size << "," << f->bebuf_size << ") ";
     f = f->next;
   }
   cout << endl;
 }


 int sc_main(int argc, char **argv) {

   #include <string>

   // no command line parameters //
   // get everything from stdin and build transaction object //
   cout << "\nTLM-2 Endianness Conversion Helper Functions Tester\n";
   cout << "March 2008\n";
   cout << "January 2012 Updated to read from endian_conv/input.txt\n\n";

   std::string filename;
   std::ifstream fin;

   if (1 == argc)
       filename = "endian_conv/input.txt";
   else if (2 == argc)
       filename = argv[1];
   else {
     std::cerr << "Too many input arguments" << std::endl;
 	return 1;
   }


   fin.open(filename.c_str(), ios_base::in);
   if (!fin) {
     std::cerr << "Could not open input filename " << filename << std::endl;
     return 1;
   }

   srand(time(NULL));
   const int nr_txns_in_pool = 7;
   const int txn_to_cycle = 4;
   tlm_generic_payload *txns[nr_txns_in_pool];
   for(int i=0; i < nr_txns_in_pool; i++) txns[i] = new tlm_generic_payload;

   for(int i=0; true; i = ((i+1) % nr_txns_in_pool)) {
     cout << i << " enter {R|W}, addr=a, len=l, bus width=b, word width=w, initiator offset=i, be={x|01}, stream width=s\n";
     pool_status();
     char command;
     fin >> command;
     if(fin.eof()) break;
     if((command != 'R') && (command != 'W')) break;
     if(i==txn_to_cycle) {
       // should cause 2 extensions to get pushed to the pool once they've been used
       delete txns[i];
       pool_status();
       delete txns[i-1];
       pool_status();
       // and popped back later when these new ones establish contexts
       txns[i] = new tlm_generic_payload;
       txns[i-1] = new tlm_generic_payload;
       pool_status();
     }
     test_a_conversion(command, *txns[i], fin);
   }

   for(int i=0; i < nr_txns_in_pool; i++) {
     delete txns[i];
     pool_status();
   }
   return 0;
 }


 // converter functions for non-aligned single transactions
 // included here for validation only.  not designed for general use.

 unsigned char *original_dptr;
 sc_dt::uint64 original_addr;

 template<class DATAWORD> inline void
 local_single_tohe(tlm_generic_payload *txn, unsigned int sizeof_databus) {
   if(txn->get_data_length() != sizeof(DATAWORD)) {
     cout << "Error:  local_single_tohe() wrongly called\n";
     exit(1);
   }

   sc_dt::uint64 mask = sizeof_databus - 1;

   // set up new buffers, length and address
   if(sizeof(DATAWORD) > sizeof_databus)
     txn->set_data_length(sizeof_databus + sizeof(DATAWORD));
   else
     txn->set_data_length(2 * sizeof_databus);
   txn->set_streaming_width(txn->get_data_length());
   unsigned char *new_data = new unsigned char[txn->get_data_length()];
   unsigned char *new_be = new unsigned char[txn->get_data_length()];
   // drive all BEs to zero initially
   for(unsigned int i=0; i<txn->get_data_length(); i++) new_be[i] = 0;
   sc_dt::uint64 new_addr = txn->get_address() & ~mask;

   // Comments assume arithmetic mode big endian initiator modelled on little
   // endian host (but the functionality is the same for LE initiator on BE host)

   // iterate over the initiator word byte by byte, MSB first
   unsigned char *curr_d = txn->get_data_ptr() + sizeof(DATAWORD) - 1;
   unsigned char *curr_b = txn->get_byte_enable_ptr() + sizeof(DATAWORD) - 1;

   // initiator intent is to put the MSB at the address given in the transaction
   sc_dt::uint64 curr_a = txn->get_address();

   // iterate copying data and byte enables
   for( ; curr_d >= txn->get_data_ptr(); curr_d--, curr_b--, curr_a++) {
     // work out the address in the TLM interpretation of the initiator's intent
     sc_dt::uint64 he_addr = curr_a ^ mask;
     int idx = he_addr - new_addr;
     if(txn->is_write()) new_data[idx] = *curr_d;
     if(txn->get_byte_enable_ptr() == 0) new_be[idx] = 1;
     else new_be[idx] = *curr_b;
   }

   // replace the pointers
   original_dptr = txn->get_data_ptr();
   txn->set_data_ptr(new_data);
   txn->set_byte_enable_ptr(new_be);
   txn->set_byte_enable_length(txn->get_data_length());
   original_addr = txn->get_address();
   txn->set_address(new_addr);
 }


 template<class DATAWORD> inline void
 local_single_fromhe(tlm_generic_payload *txn, unsigned int sizeof_databus) {
   sc_dt::uint64 mask = sizeof_databus - 1;

   // Comments assume arithmetic mode big endian initiator modelled on little
   // endian host (but the functionality is the same for LE initiator on BE host)

   // iterate over the initiator word byte by byte, MSB first
   unsigned char *curr_d = original_dptr + sizeof(DATAWORD) - 1;

   // initiator intent is to put the MSB at the address given in the transaction
   sc_dt::uint64 curr_a = original_addr;

   // iterate copying data and byte enables
   for( ; curr_d >= original_dptr; curr_d--, curr_a++) {
     // work out the address in the TLM interpretation of the initiator's intent
     sc_dt::uint64 he_addr = curr_a ^ mask;
     int idx = he_addr - txn->get_address();
     if((txn->is_read()) && (txn->get_byte_enable_ptr()[idx] != 0))
       *curr_d = txn->get_data_ptr()[idx];
   }

   // clean up
   delete [] txn->get_data_ptr();
   delete [] txn->get_byte_enable_ptr();
 }
	/*****************************************************************************

	Licensed to Accellera Systems Initiative Inc. (Accellera) under one or
	more contributor license agreements. See the NOTICE file distributed
	with this work for additional information regarding copyright ownership.
	Accellera licenses this file to you under the Apache License, Version 2.0
	(the "License"); you may not use this file except in compliance with the
	License. You may obtain a copy of the License at

	http://www.apache.org/licenses/LICENSE-2.0

	Unless required by applicable law or agreed to in writing, software
	distributed under the License is distributed on an "AS IS" BASIS,
	WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or
	implied. See the License for the specific language governing
	permissions and limitations under the License.

	*****************************************************************************/


	/*
	This C++ programme runs single transactions through a single
	endianness conversion function, then through a simple memory model,
	then converts it back.
	Takes the initial memory state as input and provides the final
	memory state as output.
	*/


	#define BUFFER_SIZE 2048

	#include<systemc>
	#include "tlm.h"
	#include<iostream>
	#include<time.h>
	#include <fstream>

	using namespace std;
	using namespace tlm;
	using namespace sc_dt;


	// simple set of types with known sizeof(), for testing //
	template<int SIZE> class dt {
	char content[SIZE];
	};


	#define convert(function) \
	switch(data_width) { \
	case 1: function<dt<1> >(&txn,bus_width); break; \
	case 2: function<dt<2> >(&txn,bus_width); break; \
	case 4: function<dt<4> >(&txn,bus_width); break; \
	case 8: function<dt<8> >(&txn,bus_width); break; \
	case 16: function<dt<16> >(&txn,bus_width); break; \
	case 32: function<dt<32> >(&txn,bus_width); break; \
	default: cout << "bad data width\n"; \
	exit(1); \
	}


	// forward declarations - see below
	template<class DATAWORD> inline void
	local_single_tohe(tlm_generic_payload *txn, unsigned int sizeof_databus);
	template<class DATAWORD> inline void
	local_single_fromhe(tlm_generic_payload *txn, unsigned int sizeof_databus);


	void test_a_conversion(char cmd, tlm_generic_payload &txn, std::ifstream & fin) {

	if(cmd == 'R') txn.set_read();
	else txn.set_write();

	fin.ignore(10000,'=');
	uint64 a;
	fin >> a;
	txn.set_address(a);

	fin.ignore(10000,'=');
	int l;
	fin >> l;
	txn.set_data_length(l);

	int bus_width;
	fin.ignore(10000,'='); fin >> bus_width;

	int data_width;
	fin.ignore(10000,'='); fin >> data_width;

	int initiator_offset;
	fin.ignore(10000,'='); fin >> initiator_offset;

	unsigned char *original_byte_enable = 0;
	unsigned char *byte_enable_legible =
	new unsigned char[txn.get_data_length() + 1];
	memset(byte_enable_legible, 0, txn.get_data_length() + 1);
	fin.ignore(10000,'=');
	for(unsigned b=0; b<txn.get_data_length(); b++) {
	char tmp; fin >> tmp;
	if((tmp=='0')\|\|(tmp=='1')\|\|(tmp=='x')) byte_enable_legible[b]=tmp;
	else break;
	}
	if((byte_enable_legible[0] == '1') \|\| (byte_enable_legible[0] == '0')) {
	txn.set_byte_enable_ptr(new unsigned char[txn.get_data_length()]);
	txn.set_byte_enable_length(txn.get_data_length());
	original_byte_enable = txn.get_byte_enable_ptr();
	for(unsigned int i=0; i<txn.get_data_length(); i++) {
	if(byte_enable_legible[i] == '0') {
	txn.get_byte_enable_ptr()[i] = TLM_BYTE_DISABLED;
	} else if(byte_enable_legible[i] == '1') {
	txn.get_byte_enable_ptr()[i] = TLM_BYTE_ENABLED;
	} else {
	// not enough byte enables
	txn.set_byte_enable_length(i);
	break;
	}
	}
	} else {
	txn.set_byte_enable_ptr(0);
	txn.set_byte_enable_length(0);
	}

	int stream_width;
	fin.ignore(10000,'='); fin >> stream_width;
	txn.set_streaming_width(stream_width);

	cout << "enter initiator memory state = ("<< BUFFER_SIZE << " characters)\n";
	unsigned char initiator_mem[BUFFER_SIZE+1];
	memset(initiator_mem, 0, BUFFER_SIZE+1);
	fin.ignore(10000,'='); fin >> initiator_mem;

	txn.set_data_ptr(initiator_mem + initiator_offset);

	cout << "enter target memory state = ("<< BUFFER_SIZE << " characters)\n";
	unsigned char target_mem[BUFFER_SIZE+1];
	memset(target_mem, 0, BUFFER_SIZE+1);
	fin.ignore(10000,'='); fin >> target_mem;

	cout << "enter converter choice = (0 => generic, 1 => word, 2 => aligned, 3 => single)\n";
	int converter;
	fin.ignore(10000,'='); fin >> converter;

	cout << "Initiator Intent\n";
	cout << " Cmd = " << cmd << endl;
	cout << " Addr = " << txn.get_address() << endl;
	cout << " Len = " << txn.get_data_length() << endl;
	cout << " Bus Width = " << bus_width << endl;
	cout << " Data Word = " << data_width << endl;
	#ifdef VERBOSE
	cout << " Initiator offset and txn data pointer = " << initiator_offset << ", " << int(txn.get_data_ptr()) << endl;
	cout << " Byte enables and byte enable pointer = " << byte_enable_legible << ", " << int(txn.get_byte_enable_ptr()) << endl;
	#else
	cout << " Initiator offset = " << initiator_offset << endl;
	cout << " Byte enables = " << byte_enable_legible << endl;
	#endif
	cout << " Byte enable length = " << txn.get_byte_enable_length() << endl;
	cout << " Streaming width = " << txn.get_streaming_width() << endl;
	cout << " Initiator memory = " << initiator_mem << endl;
	cout << " Target memory = " << target_mem << endl;
	cout << " Converter = " << converter << endl << endl;

	// initiator //
	switch(converter) {
	case 0: convert(tlm_to_hostendian_generic); break;
	case 1: convert(tlm_to_hostendian_word); break;
	case 2: convert(tlm_to_hostendian_aligned); break;
	case 3: convert(tlm_to_hostendian_single); break;
	case 4: convert(local_single_tohe); break;
	default: cout << "no such converter as " << converter << endl;
	exit(1);
	}

	cout << "Converted Transaction\n";
	cout << " Addr = " << txn.get_address() << endl;
	cout << " Len = " << txn.get_data_length() << endl;
	#ifdef VERBOSE
	cout << " Txn data pointer = " << int(txn.get_data_ptr()) << endl;
	if(txn.get_byte_enable_ptr() != 0) {
	cout << " Byte enables and byte enable pointer = ";
	for(unsigned int i=0; i<txn.get_data_length(); i++)
	cout << (txn.get_byte_enable_ptr()[i] ? '1' : '0');
	cout << ", " << int(txn.get_byte_enable_ptr()) << endl;
	}
	#else
	cout << " Txn data pointer = " <<
	(txn.get_data_ptr() == initiator_mem+initiator_offset ? "unchanged" : "changed") << endl;
	if(txn.get_byte_enable_ptr() != 0) {
	cout << " Byte enables and byte enable pointer = ";
	for(unsigned int i=0; i<txn.get_data_length(); i++)
	cout << (txn.get_byte_enable_ptr()[i] ? '1' : '0');
	cout << ", " <<
	(txn.get_byte_enable_ptr() == original_byte_enable ? "unchanged" : "changed") << endl;
	}
	#endif
	cout << " Byte enable length = " << txn.get_byte_enable_length() << endl;
	cout << " Streaming width = " << txn.get_streaming_width() << endl;
	cout << endl;

	// target //
	int sw = txn.get_streaming_width();
	if((txn.get_data_length()/sw)*sw != txn.get_data_length()) {
	cout << "ERROR: Data length not a multiple of streaming width\n";
	exit(1);
	}
	for(unsigned int ss = 0; ss < txn.get_data_length(); ss += sw) {
	if(txn.get_byte_enable_ptr() == 0) {
	// simple transaction can be processed by mem-copy
	if(txn.is_read())
	memcpy(ss+txn.get_data_ptr(), target_mem+txn.get_address(), sw);
	else
	memcpy(target_mem+txn.get_address(), ss+txn.get_data_ptr(), sw);
	} else {
	// complex transaction, byte enables, maybe shorter than data
	int bel = txn.get_byte_enable_length();
	if(txn.is_read()) {
	for(int j=0; j<sw; j++) {
	if(txn.get_byte_enable_ptr()[(ss+j) % bel])
	(txn.get_data_ptr())[ss+j] = target_mem[j+txn.get_address()];
	}
	} else {
	for(int j=0; j<sw; j++) {
	if(txn.get_byte_enable_ptr()[(ss+j) % bel])
	target_mem[j+txn.get_address()] = (txn.get_data_ptr())[ss+j];
	}
	}
	}
	}

	// initiator again //
	if((rand() & 0x100) && (converter < 4)) {
	#ifdef VERBOSE
	cout << "using single entry point for response\n";
	#endif
	tlm_from_hostendian(&txn);
	} else {
	#ifdef VERBOSE
	cout << "using specific entry point for response\n";
	#endif
	switch(converter) {
	case 0: convert(tlm_from_hostendian_generic); break;
	case 1: convert(tlm_from_hostendian_word); break;
	case 2: convert(tlm_from_hostendian_aligned); break;
	case 3: convert(tlm_from_hostendian_single); break;
	case 4: convert(local_single_fromhe); break;
	default: cout << "no such converter as " << converter << endl;
	exit(1);
	}
	}

	// print the results //
	cout << "Memory States after Transaction\n";
	cout << " initiator = " << initiator_mem << endl;
	cout << " target = " << target_mem << endl << endl;

	// clean up
	delete [] byte_enable_legible;
	if(original_byte_enable != 0) delete [] original_byte_enable;
	}


	void pool_status() {
	cout << "Pool status: ";
	tlm_endian_context *f = global_tlm_endian_context_pool.first;
	while(f!=0) {
	cout << "(" << f->dbuf_size << "," << f->bebuf_size << ") ";
	f = f->next;
	}
	cout << endl;
	}


	int sc_main(int argc, char **argv) {

	#include <string>

	// no command line parameters //
	// get everything from stdin and build transaction object //
	cout << "\nTLM-2 Endianness Conversion Helper Functions Tester\n";
	cout << "March 2008\n";
	cout << "January 2012 Updated to read from endian_conv/input.txt\n\n";

	std::string filename;
	std::ifstream fin;

	if (1 == argc)
	filename = "endian_conv/input.txt";
	else if (2 == argc)
	filename = argv[1];
	else {
	std::cerr << "Too many input arguments" << std::endl;
	return 1;
	}


	fin.open(filename.c_str(), ios_base::in);
	if (!fin) {
	std::cerr << "Could not open input filename " << filename << std::endl;
	return 1;
	}

	srand(time(NULL));
	const int nr_txns_in_pool = 7;
	const int txn_to_cycle = 4;
	tlm_generic_payload *txns[nr_txns_in_pool];
	for(int i=0; i < nr_txns_in_pool; i++) txns[i] = new tlm_generic_payload;

	for(int i=0; true; i = ((i+1) % nr_txns_in_pool)) {
	cout << i << " enter {R\|W}, addr=a, len=l, bus width=b, word width=w, initiator offset=i, be={x\|01}, stream width=s\n";
	pool_status();
	char command;
	fin >> command;
	if(fin.eof()) break;
	if((command != 'R') && (command != 'W')) break;
	if(i==txn_to_cycle) {
	// should cause 2 extensions to get pushed to the pool once they've been used
	delete txns[i];
	pool_status();
	delete txns[i-1];
	pool_status();
	// and popped back later when these new ones establish contexts
	txns[i] = new tlm_generic_payload;
	txns[i-1] = new tlm_generic_payload;
	pool_status();
	}
	test_a_conversion(command, *txns[i], fin);
	}

	for(int i=0; i < nr_txns_in_pool; i++) {
	delete txns[i];
	pool_status();
	}
	return 0;
	}


	// converter functions for non-aligned single transactions
	// included here for validation only. not designed for general use.

	unsigned char *original_dptr;
	sc_dt::uint64 original_addr;

	template<class DATAWORD> inline void
	local_single_tohe(tlm_generic_payload *txn, unsigned int sizeof_databus) {
	if(txn->get_data_length() != sizeof(DATAWORD)) {
	cout << "Error: local_single_tohe() wrongly called\n";
	exit(1);
	}

	sc_dt::uint64 mask = sizeof_databus - 1;

	// set up new buffers, length and address
	if(sizeof(DATAWORD) > sizeof_databus)
	txn->set_data_length(sizeof_databus + sizeof(DATAWORD));
	else
	txn->set_data_length(2 * sizeof_databus);
	txn->set_streaming_width(txn->get_data_length());
	unsigned char *new_data = new unsigned char[txn->get_data_length()];
	unsigned char *new_be = new unsigned char[txn->get_data_length()];
	// drive all BEs to zero initially
	for(unsigned int i=0; i<txn->get_data_length(); i++) new_be[i] = 0;
	sc_dt::uint64 new_addr = txn->get_address() & ~mask;

	// Comments assume arithmetic mode big endian initiator modelled on little
	// endian host (but the functionality is the same for LE initiator on BE host)

	// iterate over the initiator word byte by byte, MSB first
	unsigned char *curr_d = txn->get_data_ptr() + sizeof(DATAWORD) - 1;
	unsigned char *curr_b = txn->get_byte_enable_ptr() + sizeof(DATAWORD) - 1;

	// initiator intent is to put the MSB at the address given in the transaction
	sc_dt::uint64 curr_a = txn->get_address();

	// iterate copying data and byte enables
	for( ; curr_d >= txn->get_data_ptr(); curr_d--, curr_b--, curr_a++) {
	// work out the address in the TLM interpretation of the initiator's intent
	sc_dt::uint64 he_addr = curr_a ^ mask;
	int idx = he_addr - new_addr;
	if(txn->is_write()) new_data[idx] = *curr_d;
	if(txn->get_byte_enable_ptr() == 0) new_be[idx] = 1;
	else new_be[idx] = *curr_b;
	}

	// replace the pointers
	original_dptr = txn->get_data_ptr();
	txn->set_data_ptr(new_data);
	txn->set_byte_enable_ptr(new_be);
	txn->set_byte_enable_length(txn->get_data_length());
	original_addr = txn->get_address();
	txn->set_address(new_addr);
	}


	template<class DATAWORD> inline void
	local_single_fromhe(tlm_generic_payload *txn, unsigned int sizeof_databus) {
	sc_dt::uint64 mask = sizeof_databus - 1;

	// Comments assume arithmetic mode big endian initiator modelled on little
	// endian host (but the functionality is the same for LE initiator on BE host)

	// iterate over the initiator word byte by byte, MSB first
	unsigned char *curr_d = original_dptr + sizeof(DATAWORD) - 1;

	// initiator intent is to put the MSB at the address given in the transaction
	sc_dt::uint64 curr_a = original_addr;

	// iterate copying data and byte enables
	for( ; curr_d >= original_dptr; curr_d--, curr_a++) {
	// work out the address in the TLM interpretation of the initiator's intent
	sc_dt::uint64 he_addr = curr_a ^ mask;
	int idx = he_addr - txn->get_address();
	if((txn->is_read()) && (txn->get_byte_enable_ptr()[idx] != 0))
	*curr_d = txn->get_data_ptr()[idx];
	}

	// clean up
	delete [] txn->get_data_ptr();
	delete [] txn->get_byte_enable_ptr();
	}