src/mem/ruby/slicc_interface/RubyRequest.cc - arm/gem5 - Git at Google

 #include <iostream>

 #include "mem/ruby/slicc_interface/RubyRequest.hh"

 using namespace std;

 void
 RubyRequest::print(ostream& out) const
 {
   out << "[RubyRequest: ";
   out << "LineAddress = " << m_LineAddress << " ";
   out << "PhysicalAddress = " << m_PhysicalAddress << " ";
   out << "Type = " << m_Type << " ";
   out << "ProgramCounter = " << m_ProgramCounter << " ";
   out << "AccessMode = " << m_AccessMode << " ";
   out << "Size = " << m_Size << " ";
   out << "Prefetch = " << m_Prefetch << " ";
 //  out << "Time = " << getTime() << " ";
   out << "]";
 }

 bool
 RubyRequest::functionalRead(Packet *pkt)
 {
     // This needs a little explanation. Initially I thought that this
     // message should be read. But the way the memtester works for now,
     // we should not be reading this message as memtester updates the
     // functional memory only after a write has actually taken place.
     return false;
 }

 bool
 RubyRequest::functionalWrite(Packet *pkt)
 {
     // This needs a little explanation. I am not sure if this message
     // should be written. Essentially the question is how are writes
     // ordered. I am assuming that if a functional write is issued after
     // a timing write to the same address, then the functional write
     // has to overwrite the data for the timing request, even if the
     // timing request has still not been ordered globally.

     Addr wBase = pkt->getAddr();
     Addr wTail = wBase + pkt->getSize();
     Addr mBase = m_PhysicalAddress.getAddress();
     Addr mTail = mBase + m_Size;

     uint8_t * pktData = pkt->getPtr<uint8_t>(true);

     Addr cBase = std::max(wBase, mBase);
     Addr cTail = std::min(wTail, mTail);

     for (Addr i = cBase; i < cTail; ++i) {
         data[i - mBase] = pktData[i - wBase];
     }

     return cBase < cTail;
 }
	#include <iostream>

	#include "mem/ruby/slicc_interface/RubyRequest.hh"

	using namespace std;

	void
	RubyRequest::print(ostream& out) const
	{
	out << "[RubyRequest: ";
	out << "LineAddress = " << m_LineAddress << " ";
	out << "PhysicalAddress = " << m_PhysicalAddress << " ";
	out << "Type = " << m_Type << " ";
	out << "ProgramCounter = " << m_ProgramCounter << " ";
	out << "AccessMode = " << m_AccessMode << " ";
	out << "Size = " << m_Size << " ";
	out << "Prefetch = " << m_Prefetch << " ";
	// out << "Time = " << getTime() << " ";
	out << "]";
	}

	bool
	RubyRequest::functionalRead(Packet *pkt)
	{
	// This needs a little explanation. Initially I thought that this
	// message should be read. But the way the memtester works for now,
	// we should not be reading this message as memtester updates the
	// functional memory only after a write has actually taken place.
	return false;
	}

	bool
	RubyRequest::functionalWrite(Packet *pkt)
	{
	// This needs a little explanation. I am not sure if this message
	// should be written. Essentially the question is how are writes
	// ordered. I am assuming that if a functional write is issued after
	// a timing write to the same address, then the functional write
	// has to overwrite the data for the timing request, even if the
	// timing request has still not been ordered globally.

	Addr wBase = pkt->getAddr();
	Addr wTail = wBase + pkt->getSize();
	Addr mBase = m_PhysicalAddress.getAddress();
	Addr mTail = mBase + m_Size;

	uint8_t * pktData = pkt->getPtr<uint8_t>(true);

	Addr cBase = std::max(wBase, mBase);
	Addr cTail = std::min(wTail, mTail);

	for (Addr i = cBase; i < cTail; ++i) {
	data[i - mBase] = pktData[i - wBase];
	}

	return cBase < cTail;
	}