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/*
* Copyright (c) 2015, University of Kaiserslautern
* Copyright (c) 2016, Dresden University of Technology (TU Dresden)
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
*
* 1. Redistributions of source code must retain the above copyright notice,
* this list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright
* notice, this list of conditions and the following disclaimer in the
* documentation and/or other materials provided with the distribution.
*
* 3. Neither the name of the copyright holder nor the names of its
* contributors may be used to endorse or promote products derived from
* this software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED
* TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
* PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER
* OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL,
* EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO,
* PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR
* PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF
* LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING
* NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "sc_ext.hh"
#include "sc_mm.hh"
#include "sc_slave_port.hh"
#include "slave_transactor.hh"
namespace Gem5SystemC
{
/**
* Instantiate a tlm memory manager that takes care about all the
* tlm transactions in the system
*/
MemoryManager mm;
/**
* Convert a gem5 packet to a TLM payload by copying all the relevant
* information to a previously allocated tlm payload
*/
void
packet2payload(PacketPtr packet, tlm::tlm_generic_payload &trans)
{
trans.set_address(packet->getAddr());
/* Check if this transaction was allocated by mm */
sc_assert(trans.has_mm());
unsigned int size = packet->getSize();
unsigned char *data = packet->getPtr<unsigned char>();
trans.set_data_length(size);
trans.set_streaming_width(size);
trans.set_data_ptr(data);
if (packet->isRead()) {
trans.set_command(tlm::TLM_READ_COMMAND);
}
else if (packet->isInvalidate()) {
/* Do nothing */
} else if (packet->isWrite()) {
trans.set_command(tlm::TLM_WRITE_COMMAND);
} else {
SC_REPORT_FATAL("SCSlavePort", "No R/W packet");
}
}
/**
* Similar to TLM's blocking transport (LT)
*/
Tick
SCSlavePort::recvAtomic(PacketPtr packet)
{
CAUGHT_UP;
SC_REPORT_INFO("SCSlavePort", "recvAtomic hasn't been tested much");
panic_if(packet->cacheResponding(), "Should not see packets where cache "
"is responding");
panic_if(!(packet->isRead() || packet->isWrite()),
"Should only see read and writes at TLM memory\n");
sc_core::sc_time delay = sc_core::SC_ZERO_TIME;
/* Prepare the transaction */
tlm::tlm_generic_payload * trans = mm.allocate();
trans->acquire();
packet2payload(packet, *trans);
/* Attach the packet pointer to the TLM transaction to keep track */
Gem5Extension* extension = new Gem5Extension(packet);
trans->set_auto_extension(extension);
/* Execute b_transport: */
if (packet->cmd == MemCmd::SwapReq) {
SC_REPORT_FATAL("SCSlavePort", "SwapReq not supported");
} else if (packet->isRead()) {
transactor->socket->b_transport(*trans, delay);
} else if (packet->isInvalidate()) {
// do nothing
} else if (packet->isWrite()) {
transactor->socket->b_transport(*trans, delay);
} else {
SC_REPORT_FATAL("SCSlavePort", "Typo of request not supported");
}
if (packet->needsResponse()) {
packet->makeResponse();
}
trans->release();
return delay.value();
}
/**
* Similar to TLM's debug transport
*/
void
SCSlavePort::recvFunctional(PacketPtr packet)
{
/* Prepare the transaction */
tlm::tlm_generic_payload * trans = mm.allocate();
trans->acquire();
packet2payload(packet, *trans);
/* Attach the packet pointer to the TLM transaction to keep track */
Gem5Extension* extension = new Gem5Extension(packet);
trans->set_auto_extension(extension);
/* Execute Debug Transport: */
unsigned int bytes = transactor->socket->transport_dbg(*trans);
if (bytes != trans->get_data_length()) {
SC_REPORT_FATAL("SCSlavePort","debug transport was not completed");
}
trans->release();
}
bool
SCSlavePort::recvTimingSnoopResp(PacketPtr packet)
{
/* Snooping should be implemented with tlm_dbg_transport */
SC_REPORT_FATAL("SCSlavePort","unimplemented func.: recvTimingSnoopResp");
return false;
}
void
SCSlavePort::recvFunctionalSnoop(PacketPtr packet)
{
/* Snooping should be implemented with tlm_dbg_transport */
SC_REPORT_FATAL("SCSlavePort","unimplemented func.: recvFunctionalSnoop");
}
/**
* Similar to TLM's non-blocking transport (AT)
*/
bool
SCSlavePort::recvTimingReq(PacketPtr packet)
{
CAUGHT_UP;
panic_if(packet->cacheResponding(), "Should not see packets where cache "
"is responding");
panic_if(!(packet->isRead() || packet->isWrite()),
"Should only see read and writes at TLM memory\n");
/* We should never get a second request after noting that a retry is
* required */
sc_assert(!needToSendRequestRetry);
/* Remember if a request comes in while we're blocked so that a retry
* can be sent to gem5 */
if (blockingRequest) {
needToSendRequestRetry = true;
return false;
}
/* NOTE: normal tlm is blocking here. But in our case we return false
* and tell gem5 when a retry can be done. This is the main difference
* in the protocol:
* if (requestInProgress)
* {
* wait(endRequestEvent);
* }
* requestInProgress = trans;
*/
/* Prepare the transaction */
tlm::tlm_generic_payload * trans = mm.allocate();
trans->acquire();
packet2payload(packet, *trans);
/* Attach the packet pointer to the TLM transaction to keep track */
Gem5Extension* extension = new Gem5Extension(packet);
trans->set_auto_extension(extension);
/*
* Pay for annotated transport delays.
*
* The header delay marks the point in time, when the packet first is seen
* by the transactor. This is the point int time, when the transactor needs
* to send the BEGIN_REQ to the SystemC world.
*
* NOTE: We drop the payload delay here. Normally, the receiver would be
* responsible for handling the payload delay. In this case, however,
* the receiver is a SystemC module and has no notion of the gem5
* transport protocol and we cannot simply forward the
* payload delay to the receiving module. Instead, we expect the
* receiving SystemC module to model the payload delay by deferring
* the END_REQ. This could lead to incorrect delays, if the XBar
* payload delay is longer than the time the receiver needs to accept
* the request (time between BEGIN_REQ and END_REQ).
*
* TODO: We could detect the case described above by remembering the
* payload delay and comparing it to the time between BEGIN_REQ and
* END_REQ. Then, a warning should be printed.
*/
auto delay = sc_core::sc_time::from_value(packet->payloadDelay);
// reset the delays
packet->payloadDelay = 0;
packet->headerDelay = 0;
/* Starting TLM non-blocking sequence (AT) Refer to IEEE1666-2011 SystemC
* Standard Page 507 for a visualisation of the procedure */
tlm::tlm_phase phase = tlm::BEGIN_REQ;
tlm::tlm_sync_enum status;
status = transactor->socket->nb_transport_fw(*trans, phase, delay);
/* Check returned value: */
if (status == tlm::TLM_ACCEPTED) {
sc_assert(phase == tlm::BEGIN_REQ);
/* Accepted but is now blocking until END_REQ (exclusion rule)*/
blockingRequest = trans;
} else if (status == tlm::TLM_UPDATED) {
/* The Timing annotation must be honored: */
sc_assert(phase == tlm::END_REQ || phase == tlm::BEGIN_RESP);
PayloadEvent<SCSlavePort> * pe;
pe = new PayloadEvent<SCSlavePort>(*this,
&SCSlavePort::pec, "PEQ");
pe->notify(*trans, phase, delay);
} else if (status == tlm::TLM_COMPLETED) {
/* Transaction is over nothing has do be done. */
sc_assert(phase == tlm::END_RESP);
trans->release();
}
return true;
}
void
SCSlavePort::pec(
PayloadEvent<SCSlavePort> * pe,
tlm::tlm_generic_payload& trans,
const tlm::tlm_phase& phase)
{
sc_time delay;
if (phase == tlm::END_REQ ||
&trans == blockingRequest && phase == tlm::BEGIN_RESP) {
sc_assert(&trans == blockingRequest);
blockingRequest = NULL;
/* Did another request arrive while blocked, schedule a retry */
if (needToSendRequestRetry) {
needToSendRequestRetry = false;
sendRetryReq();
}
}
if (phase == tlm::BEGIN_RESP)
{
CAUGHT_UP;
auto& extension = Gem5Extension::getExtension(trans);
auto packet = extension.getPacket();
sc_assert(!blockingResponse);
bool need_retry = false;
/*
* If the packet was piped through and needs a response, we don't need
* to touch the packet and can forward it directly as a response.
* Otherwise, we need to make a response and send the transformed
* packet.
*/
if (extension.isPipeThrough()) {
if (packet->isResponse()) {
need_retry = !sendTimingResp(packet);
}
} else if (packet->needsResponse()) {
packet->makeResponse();
need_retry = !sendTimingResp(packet);
}
if (need_retry) {
blockingResponse = &trans;
} else {
if (phase == tlm::BEGIN_RESP) {
/* Send END_RESP and we're finished: */
tlm::tlm_phase fw_phase = tlm::END_RESP;
sc_time delay = SC_ZERO_TIME;
transactor->socket->nb_transport_fw(trans, fw_phase, delay);
/* Release the transaction with all the extensions */
trans.release();
}
}
}
delete pe;
}
void
SCSlavePort::recvRespRetry()
{
CAUGHT_UP;
/* Retry a response */
sc_assert(blockingResponse);
tlm::tlm_generic_payload *trans = blockingResponse;
blockingResponse = NULL;
PacketPtr packet = Gem5Extension::getExtension(trans).getPacket();
bool need_retry = !sendTimingResp(packet);
sc_assert(!need_retry);
sc_core::sc_time delay = sc_core::SC_ZERO_TIME;
tlm::tlm_phase phase = tlm::END_RESP;
transactor->socket->nb_transport_fw(*trans, phase, delay);
// Release transaction with all the extensions
trans->release();
}
tlm::tlm_sync_enum
SCSlavePort::nb_transport_bw(tlm::tlm_generic_payload& trans,
tlm::tlm_phase& phase,
sc_core::sc_time& delay)
{
PayloadEvent<SCSlavePort> * pe;
pe = new PayloadEvent<SCSlavePort>(*this, &SCSlavePort::pec, "PE");
pe->notify(trans, phase, delay);
return tlm::TLM_ACCEPTED;
}
SCSlavePort::SCSlavePort(const std::string &name_,
const std::string &systemc_name,
ExternalSlave &owner_) :
ExternalSlave::Port(name_, owner_),
blockingRequest(NULL),
needToSendRequestRetry(false),
blockingResponse(NULL),
transactor(nullptr)
{
}
void
SCSlavePort::bindToTransactor(Gem5SlaveTransactor* transactor)
{
sc_assert(this->transactor == nullptr);
this->transactor = transactor;
transactor->socket.register_nb_transport_bw(this,
&SCSlavePort::nb_transport_bw);
}
ExternalSlave::Port*
SCSlavePortHandler::getExternalPort(const std::string &name,
ExternalSlave &owner,
const std::string &port_data)
{
// Create and register a new SystemC slave port
auto* port = new SCSlavePort(name, port_data, owner);
control.registerSlavePort(port_data, port);
return port;
}
}