simpleattarget2.h

SystemC Transaction Level Modelling. 是基于SystemC之上的总线互联协议

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  source code Copyright (c) 1996-2008 by all Contributors.
  All Rights reserved.

  The contents of this file are subject to the restrictions and limitations
  set forth in the SystemC Open Source License Version 3.0 (the "License");
  You may not use this file except in compliance with such restrictions and
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  License at http://www.systemc.org/. Software distributed by Contributors
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  language governing rights and limitations under the License.

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#ifndef __SIMPLE_AT_TARGET2_H__
#define __SIMPLE_AT_TARGET2_H__

#include "tlm.h"
#include "tlm_utils/simple_target_socket.h"
//#include <systemc>
#include <cassert>
#include <vector>
#include <queue>
//#include <iostream>

class SimpleATTarget2 : public sc_core::sc_module
{
public:
  typedef tlm::tlm_generic_payload            transaction_type;
  typedef tlm::tlm_phase                      phase_type;
  typedef tlm::tlm_sync_enum                  sync_enum_type;
  typedef tlm_utils::simple_target_socket<SimpleATTarget2> target_socket_type;

public:
  target_socket_type socket;

public:
  SC_HAS_PROCESS(SimpleATTarget2);
  SimpleATTarget2(sc_core::sc_module_name name) :
    sc_core::sc_module(name),
    socket("socket"),
    ACCEPT_DELAY(25, sc_core::SC_NS),
    RESPONSE_DELAY(100, sc_core::SC_NS)
  {
    // register nb_transport method
    socket.register_nb_transport_fw(this, &SimpleATTarget2::myNBTransport);

    SC_METHOD(beginResponse)
    sensitive << mBeginResponseEvent;
    dont_initialize();

    SC_METHOD(endResponse)
    sensitive << mEndResponseEvent;
    dont_initialize();
  }

  //
  // Simple AT-TA target
  // - Request is accepted after fixed delay (relative to end of prev request
  //   phase)
  // - Response is started after fixed delay (relative to end of prev resp
  //   phase)
  //
  sync_enum_type myNBTransport(transaction_type& trans,
                               phase_type& phase,
                               sc_core::sc_time& t)
  {
    if (phase == tlm::BEGIN_REQ) {
      // transactions may be kept in queue after the initiator has send END_REQ
      trans.acquire();

      sc_dt::uint64 address = trans.get_address();
      assert(address < 400);

      unsigned int& data = *reinterpret_cast<unsigned int*>(trans.get_data_ptr());
      if (trans.get_command() == tlm::TLM_WRITE_COMMAND) {
        std::cout << name() << ": Received write request: A = 0x"
                  << std::hex << (unsigned int)address << ", D = 0x" << data
                  << std::dec << " @ " << sc_core::sc_time_stamp()
                  << std::endl;

        *reinterpret_cast<unsigned int*>(&mMem[address]) = data;

      } else {
        std::cout << name() << ": Received read request: A = 0x"
                  << std::hex << (unsigned int)address
                  << std::dec << " @ " << sc_core::sc_time_stamp()
                  << std::endl;

        data = *reinterpret_cast<unsigned int*>(&mMem[address]);
      }

      // End request phase after accept delay
      t += ACCEPT_DELAY;
      phase = tlm::END_REQ;

      if (mResponseQueue.empty()) {
        // Start processing transaction after accept delay
        // Notify begin of response phase after accept delay + response delay
        mBeginResponseEvent.notify(t + RESPONSE_DELAY);
      }
      mResponseQueue.push(&trans);

      // AT-noTA target
      // - always return false
      // - immediately return delay to indicate end of phase
      return tlm::TLM_UPDATED;

    } else if (phase == tlm::END_RESP) {

      // response phase ends after t
      mEndResponseEvent.notify(t);

      return tlm::TLM_COMPLETED;
    }

    // Not possible
    assert(0); exit(1);
//    return tlm::TLM_COMPLETED;  //unreachable code
  }

  void beginResponse()
  {
    assert(!mResponseQueue.empty());
    // start response phase of oldest transaction
    phase_type phase = tlm::BEGIN_RESP;
    sc_core::sc_time t = sc_core::SC_ZERO_TIME;
    transaction_type* trans = mResponseQueue.front();
    assert(trans);

    // Set response data
    trans->set_response_status(tlm::TLM_OK_RESPONSE);
    if (trans->get_command() == tlm::TLM_READ_COMMAND) {
       sc_dt::uint64 address = trans->get_address();
       assert(address < 400);
      *reinterpret_cast<unsigned int*>(trans->get_data_ptr()) =
        *reinterpret_cast<unsigned int*>(&mMem[address]);
    }

    if (socket->nb_transport_bw(*trans, phase, t) == tlm::TLM_COMPLETED) {
      // response phase ends after t
      mEndResponseEvent.notify(t);

    } else {
      // initiator will call nb_transport to indicate end of response phase
    }
  }

  void endResponse()
  {
    assert(!mResponseQueue.empty());
    mResponseQueue.front()->release();
    mResponseQueue.pop();

    // Start processing next transaction when previous response is accepted.
    // Notify begin of response phase after RESPONSE delay
    if (!mResponseQueue.empty()) {
      mBeginResponseEvent.notify(RESPONSE_DELAY);
    }
  }

private:
  const sc_core::sc_time ACCEPT_DELAY;
  const sc_core::sc_time RESPONSE_DELAY;

private:
  unsigned char mMem[400];
  std::queue<transaction_type*> mResponseQueue;
  sc_core::sc_event mBeginResponseEvent;
  sc_core::sc_event mEndResponseEvent;
};

#endif