path: root/src/systemc/tests/include/SimpleLTInitiator1_DMI.h

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//====================================================================
//  Nov 06, 2008
//
//  Updated by:
//    Xiaopeng Qiu, JEDA Technologies, Inc
//    Email:  qiuxp@jedatechnologies.net
//
//  To fix violations of TLM2.0 rules, which are detected by JEDA 
//  TLM2.0 checker.
//
//====================================================================

#ifndef __SIMPLE_LT_INITIATOR1_DMI_H__
#define __SIMPLE_LT_INITIATOR1_DMI_H__

#include "tlm.h"
#include <systemc>
#include <cassert>
#include <iostream>
#include <iomanip>

class SimpleLTInitiator1_dmi :
  public sc_core::sc_module,
  public virtual tlm::tlm_bw_transport_if<>
{
public:
  typedef tlm::tlm_generic_payload      transaction_type;
  typedef tlm::tlm_dmi                  dmi_type;
  typedef tlm::tlm_phase                phase_type;
  typedef tlm::tlm_sync_enum            sync_enum_type;
  typedef tlm::tlm_fw_transport_if<>    fw_interface_type;
  typedef tlm::tlm_bw_transport_if<>    bw_interface_type;
  typedef tlm::tlm_initiator_socket<>   initiator_socket_type;

public:
  initiator_socket_type socket;

public:
  SC_HAS_PROCESS(SimpleLTInitiator1_dmi);
  SimpleLTInitiator1_dmi(sc_core::sc_module_name name,
                         unsigned int nrOfTransactions = 0x5,
                         unsigned int baseAddress = 0x0) :
    sc_core::sc_module(name),
    socket("socket"),
    mNrOfTransactions(nrOfTransactions),
    mBaseAddress(baseAddress),
    mTransactionCount(0)
  {
    invalidate(mDMIData);

    // Bind this initiator's interface to the initiator socket
    socket(*this);

    // Initiator thread
    SC_THREAD(run);
  }

  bool initTransaction(transaction_type& trans)
  {
    // initialize DMI hint:
    trans.set_dmi_allowed(false);

    if (mTransactionCount < mNrOfTransactions) {
      trans.set_address(mBaseAddress + 4*mTransactionCount);
      mData = mTransactionCount;
      trans.set_command(tlm::TLM_WRITE_COMMAND);

    } else if (mTransactionCount < 2 * mNrOfTransactions) {
      trans.set_address(mBaseAddress + 4*(mTransactionCount-mNrOfTransactions));
      mData = 0;
      trans.set_command(tlm::TLM_READ_COMMAND);

    } else {
      return false;
    }

    trans.set_data_ptr(reinterpret_cast<unsigned char*>(&mData));
    trans.set_data_length(4);
    trans.set_streaming_width(4);

    ++mTransactionCount;
    return true;
  }

  void logStartTransation(transaction_type& trans)
  {
    if (trans.get_command() == tlm::TLM_WRITE_COMMAND) {
      std::cout << name() << ": Send write request: A = 0x"
                << std::hex << (unsigned int)trans.get_address()
                << ", D = 0x" << mData << std::dec
                << " @ " << sc_core::sc_time_stamp() << std::endl;
      
    } else {
      std::cout << name() << ": Send read request: A = 0x"
                << std::hex << (unsigned int)trans.get_address() << std::dec
                << " @ " << sc_core::sc_time_stamp() << std::endl;
    }
  }

  void logEndTransaction(transaction_type& trans)
  {
    if (trans.get_response_status() != tlm::TLM_OK_RESPONSE) {
      std::cout << name() << ": Received error response @ "
                << sc_core::sc_time_stamp() << std::endl;

    } else {
      std::cout << name() <<  ": Received ok response";
      if (trans.get_command() == tlm::TLM_READ_COMMAND) {
        std::cout << ": D = 0x" << std::hex << mData << std::dec;
      }
      std::cout << " @ " << sc_core::sc_time_stamp() << std::endl;
    }
  }

  void run()
  {
    transaction_type trans;
    phase_type phase;
    sc_core::sc_time t;
    
    while (initTransaction(trans)) {
      // Create transaction and initialise phase and t
      phase = tlm::BEGIN_REQ;
      t = sc_core::SC_ZERO_TIME;

      logStartTransation(trans);

      ///////////////////////////////////////////////////////////
      // DMI handling:
      // We use the DMI hint to check if it makes sense to ask for
      // DMI pointers. The pattern is:
      // - if the address is covered by a DMI region do a DMI access
      // - otherwise do a normal transaction
      //   -> check if we get a DMI hint and acquire the DMI pointers if it is
      //      set
      ///////////////////////////////////////////////////////////

      // Check if the address is covered by our DMI region
      if ( (trans.get_address() >= mDMIData.get_start_address()) &&
           (trans.get_address() <= mDMIData.get_end_address()) ) {
          // We can handle the data here. As the logEndTransaction is assuming
          // something to happen in the data structure, we really need to
          // do this:
          trans.set_response_status(tlm::TLM_OK_RESPONSE);
          sc_dt::uint64 tmp = trans.get_address() - mDMIData.get_start_address();
          if (trans.get_command() == tlm::TLM_WRITE_COMMAND) {
              *(unsigned int*)&mDMIData.get_dmi_ptr()[tmp] = mData;

          } else {
              mData = *(unsigned int*)&mDMIData.get_dmi_ptr()[tmp];
          }
          
          // Do the wait immediately. Note that doing the wait here eats almost
          // all the performance anyway, so we only gain something if we're
          // using temporal decoupling.
          if (trans.get_command() == tlm::TLM_WRITE_COMMAND) {
            wait(mDMIData.get_write_latency());

          } else {
            wait(mDMIData.get_read_latency());
          }
          
          logEndTransaction(trans);

      } else { // we need a full transaction
          sc_dt::uint64 addr = trans.get_address(); //Save address before it is mutated
          socket->b_transport(trans, t);
          wait(t);
          logEndTransaction(trans);
          
		  // Acquire DMI pointer on is available:
          if (trans.is_dmi_allowed())
          {
              dmi_type tmp;
              tmp.init();
              trans.set_address(addr);  //restore address, in case it was mutated.
              trans.set_write();
              if ( socket->get_direct_mem_ptr(trans, tmp)
                   && tmp.is_write_allowed() )
              {
                  mDMIData = tmp;
              }
          }
      }
    }
    wait();
  }

  sync_enum_type nb_transport_bw(transaction_type& trans, phase_type& phase, sc_core::sc_time& t)
  {
      // We should never be called
      assert(0);
      return tlm::TLM_COMPLETED;
  }

  void invalidate(dmi_type& dmiData)
  {
    dmiData.set_start_address(1);
    dmiData.set_end_address(0);
  }

  // Invalidate DMI pointer(s)
  void invalidate_direct_mem_ptr(sc_dt::uint64 start_range,
                                 sc_dt::uint64 end_range)
  {
      // do the invalidation if there is an address range overlap
      if (start_range <= mDMIData.get_end_address ()&&
          end_range >= mDMIData.get_start_address()) {
          std::cout <<  name() << ": got DMI pointer invalidation"
                    << " @ " << sc_core::sc_time_stamp() << std::endl;
          
          invalidate(mDMIData);
      } else {
          std::cout <<  name() << ": ignored DMI invalidation for addresses "
                    << std::hex << start_range << ", "
                    << end_range << std::dec
                    << " @ " << sc_core::sc_time_stamp() << std::endl;
      }
  }

  // Test for transport_dbg:
  // FIXME: use a configurable address
  void end_of_simulation()
  {
    std::cout <<  name() << ", <<SimpleLTInitiator1>>:" << std::endl
              << std::endl;
    unsigned char data[32];

    transaction_type trans;
    trans.set_address(mBaseAddress);
    trans.set_data_length(32);
    trans.set_data_ptr(data);
    trans.set_read();

    unsigned int n = socket->transport_dbg(trans);
        
    std::cout << "Mem @" << std::hex << mBaseAddress << std::endl;
    unsigned int j = 0;
        
    if (n > 0)
    {
        // always align endianness, so that we don't get a diff when
        // printing the raw data
        int e_start = 0;
        int e_end = 4;
        int e_increment = 1;
        if (!tlm::host_has_little_endianness())
        {
            e_start = 3;
            e_end = -1;
            e_increment = -1;
        }
        
        for (unsigned int i=0; i<n; i+=4)
        {
            for (int k=e_start; k!=e_end; k+=e_increment)
            {
                std::cout << std::setw(2) << std::setfill('0')
                          << (int)data[i+k];
                j++;
                if (j==16) {
                    j=0;
                    std::cout << std::endl;
                } else {
                    std::cout << " ";
                }
            }
        }
    }
    else
    {
        std::cout << "ERROR: debug transaction didn't give data." << std::endl;
    }
    std::cout << std::dec << std::endl;  
  }
private:
  dmi_type mDMIData;

  sc_core::sc_event mEndEvent;
  unsigned int mNrOfTransactions;
  unsigned int mBaseAddress;
  unsigned int mTransactionCount;
  unsigned int mData;
};

#endif