void memory::operation
(
tlm::tlm_generic_payload &gp
, sc_core::sc_time &delay_time ///< transaction delay
) {
sc_dt::uint64 address = gp.get_address(); // memory address
tlm::tlm_command command = gp.get_command(); // memory command
unsigned char *data = gp.get_data_ptr(); // data pointer
unsigned int length = gp.get_data_length(); // data length
tlm::tlm_response_status response_status = check_address(gp)
? tlm::TLM_OK_RESPONSE
: tlm::TLM_ADDRESS_ERROR_RESPONSE;
if (gp.get_byte_enable_ptr()) {
gp.set_response_status(tlm::TLM_BYTE_ENABLE_ERROR_RESPONSE);
}
else if (gp.get_streaming_width() != gp.get_data_length()) {
gp.set_response_status(tlm::TLM_BURST_ERROR_RESPONSE);
}
switch (command)
{
default:
{
gp.set_response_status(tlm::TLM_COMMAND_ERROR_RESPONSE);
break;
}
case tlm::TLM_WRITE_COMMAND:
{
if (response_status == tlm::TLM_OK_RESPONSE) {
for (unsigned int i = 0; i < length; i++) {
m_memory[address++] = data[i]; // move the data to memory
}
}
break;
}
case tlm::TLM_READ_COMMAND: {
if (response_status == tlm::TLM_OK_RESPONSE) {
for (unsigned int i = 0; i < length; i++)
{
data[i] = m_memory[address++]; // move the data from memory
}
}
break;
}
} // end switch
gp.set_response_status(response_status);
}
//==============================================================================
/// @fn memory::check_address
//
/// @brief Method to check if the gp is in the address range of this memory
//
/// @details
/// This routine used to check for errors in address space
//
//==============================================================================
tlm::tlm_response_status
memory::check_address
( tlm::tlm_generic_payload &gp
)
{
sc_dt::uint64 address = gp.get_address(); // memory address
unsigned int length = gp.get_data_length(); // data length
std::ostringstream msg;
msg.str("");
if ( address >= m_memory_size )
{
msg << "Target: " << m_ID
<<" address out-of-range";
REPORT_WARNING(filename, __FUNCTION__, msg.str());
return tlm::TLM_ADDRESS_ERROR_RESPONSE; // operation response
}
else
{
if ( (address + length) >= m_memory_size )
{
msg << "Target: " << m_ID
<< " address will go out of bounds";
REPORT_WARNING(filename, __FUNCTION__, msg.str());
return tlm::TLM_ADDRESS_ERROR_RESPONSE; // operation response
}
return tlm::TLM_OK_RESPONSE;
}
} // end check address
// TLM-2 blocking transport method
virtual void b_transport( tlm::tlm_generic_payload& trans, sc_time& delay )
{
tlm::tlm_command cmd = trans.get_command();
sc_dt::uint64 adr = trans.get_address();
unsigned char* ptr = trans.get_data_ptr();
unsigned int len = trans.get_data_length();
unsigned char* byt = trans.get_byte_enable_ptr();
unsigned int wid = trans.get_streaming_width();
// Obliged to check address range and check for unsupported features,
// i.e. byte enables, streaming, and bursts
// Can ignore DMI hint and extensions
// Using the SystemC report handler is an acceptable way of signalling an error
if (adr >= sc_dt::uint64(SIZE) || byt != 0 || len > 4 || wid < len)
SC_REPORT_ERROR("TLM-2", "Target does not support given generic payload transaction");
// Obliged to implement read and write commands
if ( cmd == tlm::TLM_READ_COMMAND ){
memcpy(ptr, &mem[adr], len);
cout << "Data: " << dec << mem[adr] <<
" is read from Address: " << dec << adr << endl;
}
else if ( cmd == tlm::TLM_WRITE_COMMAND ){
memcpy(&mem[adr], ptr, len);
cout << "Data: " << dec << mem[adr] <<
" is written into Address: " << dec << adr << endl;
}
// Obliged to set response status to indicate successful completion
trans.set_response_status( tlm::TLM_OK_RESPONSE );
}
// TLM-2 non-blocking transport method
tlm::tlm_sync_enum nb_transport_fw(int tag, tlm::tlm_generic_payload& trans,
tlm::tlm_phase& phase, sc_time& delay){
sc_dt::uint64 adr = trans.get_address();
unsigned int len = trans.get_data_length();
unsigned char* byt = trans.get_byte_enable_ptr();
unsigned int wid = trans.get_streaming_width();
// Obliged to check the transaction attributes for unsupported features
// and to generate the appropriate error response
if (byt != 0){
trans.set_response_status(tlm::TLM_BYTE_ENABLE_ERROR_RESPONSE);
return tlm::TLM_COMPLETED;
}
if(adr > this->size){
trans.set_response_status(tlm::TLM_ADDRESS_ERROR_RESPONSE);
std::cerr << "Error requesting address " << std::showbase << std::hex << adr << std::dec << std::endl;
return tlm::TLM_COMPLETED;
}
// Now queue the transaction until the annotated time has elapsed
if(phase == tlm::BEGIN_REQ){
while(this->transactionInProgress){
//std::cerr << "waiting for transactionInProgress" << std::endl;
wait(this->transactionCompleted);
}
//std::cerr << "there are no transactionInProgress" << std::endl;
this->transactionInProgress = true;
}
this->transId = tag;
m_peq.notify(trans, phase, delay);
trans.set_response_status(tlm::TLM_OK_RESPONSE);
return tlm::TLM_ACCEPTED;
}
inline void lt_target::b_transport(tlm::tlm_generic_payload& trans, sc_time& delay){
sc_dt::uint64 adr = trans.get_address() / 4;
unsigned char* ptr = trans.get_data_ptr();
unsigned int len = trans.get_data_length();
unsigned char* byt = trans.get_byte_enable_ptr();
unsigned int blen = trans.get_byte_enable_length();
unsigned int wid = trans.get_streaming_width();
if (adr >= sc_dt::uint64(mem_size) ) {
trans.set_response_status( tlm::TLM_ADDRESS_ERROR_RESPONSE );
return;
}
if ( wid < len ) {
trans.set_response_status( tlm::TLM_BURST_ERROR_RESPONSE );
return;
}
if (trans.is_read()) {
delay += rd_latency;
if ( byt != 0 ) {
for ( unsigned int i = 0; i < len; i++ )
if ( byt[i % blen] == TLM_BYTE_ENABLED ){
ptr[i] = (mem[adr+i/4] >> ((i&3)*8)) & 0xFF;
}
} else {
virtual void b_transport( tlm::tlm_generic_payload& trans, sc_time& delay )
{
tlm::tlm_command cmd = trans.get_command();
unsigned char* ptr = trans.get_data_ptr();
unsigned int len = trans.get_data_length();
unsigned char* byt = trans.get_byte_enable_ptr();
unsigned int bel = trans.get_byte_enable_length();
my_extension* ext;
trans.get_extension(ext);
assert( ext );
assert( len == ext->len );
assert( bel == ext->bel );
for (unsigned int i = 0; i < bel; i++)
assert( byt[i] == ext->byt[i] );
for (unsigned int i = 0; i < len; i++)
assert( ptr[i] == ext->ptr[i] );
if (cmd == tlm::TLM_READ_COMMAND)
{
for (unsigned int i = 0; i < len; i++)
{
data[i] = rand() % 256;
ptr[i] = data[i];
}
ext->ptr = data;
}
trans.set_dmi_allowed( true );
trans.set_response_status( tlm::TLM_OK_RESPONSE );
}
//==============================================================================
// dbg_transport implementation calls from initiators
//
//=============================================================================
unsigned int model_jxz_tlm::entry_transport_dbg (tlm::tlm_generic_payload &gp)
{
tlm::tlm_command command = gp.get_command();// memory command
unsigned char *data = gp.get_data_ptr();// data pointer
unsigned int length = gp.get_data_length();// data length
gp.set_response_status(tlm::TLM_COMMAND_ERROR_RESPONSE);
return 0;
}
//==============================================================================
bool
dmi_memory::is_address_dmi
(
tlm::tlm_generic_payload &gp
)
{
m_start_address = gp.get_address();
m_end_address = m_start_address + gp.get_data_length();
std::ostringstream msg;
msg.str("");
msg << "Initiator:" << m_ID;
bool return_status = false;
if ( ( ( m_start_address < ( m_dmi_base_address ) )
|| ( m_end_address > ( m_dmi_base_address + m_dmi_size ) )
)
)
{
// address is outside of the DMI boundaries
msg << " address is not a dmi address";
// msg << "m_start_address= " << m_start_address << " m_address= " << m_address
// << endl << " "
// << "m_end_address= " << m_end_address << " m_offset= " << m_offset << " m_dmi_size= "<< m_dmi_size;
REPORT_INFO(filename, __FUNCTION__, msg.str());
}
else if ( ( gp.get_command () == tlm::TLM_WRITE_COMMAND )
)
{
if ( (m_granted_access != tlm::tlm_dmi::DMI_ACCESS_READ )
&& ( m_granted_access != tlm::tlm_dmi::DMI_ACCESS_NONE)){
msg << " correct address and appropriate access for a GP Write Command "<<endl<<" ";
REPORT_INFO(filename, __FUNCTION__, msg.str());
return_status=true;
}
} //end if
else if ( ( gp.get_command () == tlm::TLM_READ_COMMAND )
)
{
if ( (m_granted_access != tlm::tlm_dmi::DMI_ACCESS_WRITE )
&& ( m_granted_access != tlm::tlm_dmi::DMI_ACCESS_NONE)){
msg << " correct address and appropriate access for a GP Read Command "<<endl<<" ";
REPORT_INFO(filename, __FUNCTION__, msg.str());
return_status=true;
}
} //end if
else {
// access permission does not match access required for operation
msg << " Incompatible GP Command for DMI Access Granted ";
// msg << " Gp.getcommand()= " << gp.get_command();
REPORT_INFO(filename, __FUNCTION__, msg.str());
} //end else
return return_status;
} // end check is dmi
//==============================================================================
// b_transport implementation calls from initiators
//
//=============================================================================
void model_jxz_tlm::entry_b_transport (tlm::tlm_generic_payload &gp, sc_core::
sc_time &delay_time)
{
tlm::tlm_command command = gp.get_command();// memory command
unsigned char *data = gp.get_data_ptr();// data pointer
unsigned int length = gp.get_data_length();// data length
unsigned long timefactor = ((length+BUSWIDTHBYTE-1)/BUSWIDTHBYTE)-1;
bool write_ok = true;
gp.set_response_status(tlm::TLM_COMMAND_ERROR_RESPONSE);
return;
}
// TLM-2 blocking transport method
virtual void b_transport( tlm::tlm_generic_payload& trans, sc_time& delay )
{
tlm::tlm_command cmd = trans.get_command();
sc_dt::uint64 adr = trans.get_address() / 4;
unsigned char* ptr = trans.get_data_ptr();
unsigned int len = trans.get_data_length();
unsigned char* byt = trans.get_byte_enable_ptr();
unsigned int wid = trans.get_streaming_width();
// Obliged to check address range and check for unsupported features,
// i.e. byte enables, streaming, and bursts
// Can ignore extensions
// *********************************************
// Generate the appropriate error response
// *********************************************
if (adr >= sc_dt::uint64(SIZE)) {
trans.set_response_status( tlm::TLM_ADDRESS_ERROR_RESPONSE );
return;
}
if (byt != 0) {
trans.set_response_status( tlm::TLM_BYTE_ENABLE_ERROR_RESPONSE );
return;
}
if (len > 4 || wid < len) {
trans.set_response_status( tlm::TLM_BURST_ERROR_RESPONSE );
return;
}
// Obliged to implement read and write commands
if ( cmd == tlm::TLM_READ_COMMAND )
memcpy(ptr, &mem[adr], len);
else if ( cmd == tlm::TLM_WRITE_COMMAND )
memcpy(&mem[adr], ptr, len);
// Illustrates that b_transport may block
wait(delay);
// Reset timing annotation after waiting
delay = SC_ZERO_TIME;
// *********************************************
// Set DMI hint to indicated that DMI is supported
// *********************************************
trans.set_dmi_allowed(true);
// Obliged to set response status to indicate successful completion
trans.set_response_status( tlm::TLM_OK_RESPONSE );
}
//==============================================================================
/// @fn memory::check_address
//
/// @brief Method to check if the gp is in the address range of this memory
//
/// @details
/// This routine used to check for errors in address space
//
//==============================================================================
bool memory::check_address (
tlm::tlm_generic_payload &gp
) {
sc_dt::uint64 address = gp.get_address(); // memory address
unsigned int length = gp.get_data_length(); // data length
if ( (address < 0) || (address > m_high_address) ) {
return 0;
} else if ( (address + length-1) > m_high_address ) {
return 0;
} else {
return 1;
}
} // end check address
unsigned int leon3_funclt_trap::IntrTLMPort_32::transport_dbg( int tag, tlm::tlm_generic_payload \
& trans ){
unsigned char* ptr = trans.get_data_ptr();
sc_dt::uint64 adr = trans.get_address();
if(*ptr == 0){
//Lower the interrupt
this->irqSignal = -1;
}
else{
//Raise the interrupt
this->irqSignal = adr;
}
trans.set_response_status(tlm::TLM_OK_RESPONSE);
return trans.get_data_length();
}
void peq_cb(tlm::tlm_generic_payload& trans, const tlm::tlm_phase& phase){
tlm::tlm_sync_enum status;
sc_time delay;
switch (phase){
case tlm::BEGIN_REQ:
status = send_end_req(trans);
break;
case tlm::END_RESP:
//std::cerr << "tlm::END_RESP in memory peq_cb" << std::endl;
this->transactionInProgress = false;
this->transactionCompleted.notify();
break;
case tlm::END_REQ:
case tlm::BEGIN_RESP:
SC_REPORT_FATAL("TLM-2", "Illegal transaction phase received by target");
break;
default:
if (phase == internal_ph){
// Execute the read or write commands
tlm::tlm_command cmd = trans.get_command();
sc_dt::uint64 adr = trans.get_address();
unsigned char* ptr = trans.get_data_ptr();
unsigned int len = trans.get_data_length();
if(cmd == tlm::TLM_READ_COMMAND){
for(int i = 0; i < len; i++, ptr++)
*ptr = this->mem[adr + i];
}
else if(cmd == tlm::TLM_WRITE_COMMAND){
for(int i = 0; i < len; i++, ptr++)
this->mem[adr + i] = *ptr;
}
trans.set_response_status(tlm::TLM_OK_RESPONSE);
// Target must honor BEGIN_RESP/END_RESP exclusion rule
// i.e. must not send BEGIN_RESP until receiving previous END_RESP or BEGIN_REQ
send_response(trans);
//std::cerr << "Memory reading address in memory " << std::hex << std::showbase << adr << std::endl;
}
break;
}
}
// Data interface to functional part of the model
void mmu_cache::exec_data(tlm::tlm_generic_payload& trans, sc_core::sc_time& delay, bool is_dbg) {
// Vars for payload decoding
tlm::tlm_command cmd = trans.get_command();
sc_dt::uint64 addr = trans.get_address();
unsigned char * ptr = trans.get_data_ptr();
unsigned int len = trans.get_data_length();
// Log number of reads and writes for power monitoring
if (m_pow_mon) {
if (cmd == tlm::TLM_READ_COMMAND) {
dyn_reads += (len >> 2) + 1;
} else {
virtual unsigned int transport_dbg(tlm::tlm_generic_payload & trans) {
tlm::tlm_command cmd = trans.get_command();
sc_dt::uint64 adr = trans.get_address() / 4;
unsigned char* ptr = trans.get_data_ptr();
unsigned int len = trans.get_data_length();
// Calculate the number of bytes to be actually copied
unsigned int num_bytes = (len < (SIZE - adr) * 4) ? len : (SIZE - adr) * 4;
if (cmd == tlm::TLM_READ_COMMAND)
memcpy(ptr, &mem[adr], num_bytes);
else if (cmd == tlm::TLM_WRITE_COMMAND)
memcpy(&mem[adr], ptr, num_bytes);
return num_bytes;
}
void DNP_master_device::master_cb( tlm::tlm_generic_payload &arg_Req, sc_time& delay)
{
uint32_t addr = (uint32_t) arg_Req.get_address();
uint32_t len = (uint32_t) arg_Req.get_data_length();
uint8_t *data_ptr = (uint8_t *) arg_Req.get_data_ptr();
crt_trans_id ++ ;
memset(recvd_data, 0, sizeof(recvd_data));
if (arg_Req.is_read()){
/*
* Read command
*/
DPRINTF("R @ 0x%08x(%d) <%d>\n", addr, len, crt_trans_id);
for(uint32_t i = 0; i < len; i+=4){
#ifdef DEBUG_DNP_MASTER
uint32_t *p = (uint32_t *)recvd_data;
#endif
send_req(crt_trans_id, (addr + i), recvd_data, 4, false);
wait(rsp_rcvd_ev);
memcpy((data_ptr + i), (uint32_t *)recvd_data, 4);
DPRINTF("R @ 0x%08x -- %08x \n", (addr + i), *p);
}
}else{
/*
* Write command
*/
DPRINTF("W @ 0x%08x(%d) <%d>\n", addr, len, crt_trans_id);
for (uint32_t i = 0; i < len; i+=4){
#ifdef DEBUG_DNP_MASTER
uint32_t *p = (uint32_t *)(data_ptr + i);
#endif
DPRINTF("W @ 0x%08x -- %08x\n", (addr + i), *p);
send_req(crt_trans_id, (addr + i), (data_ptr + i), 4, true);
wait(rsp_rcvd_ev);
}
}
arg_Req.set_response_status(tlm::TLM_OK_RESPONSE);
}
// TLM-2 debug transaction method
unsigned int transport_dbg(int tag, tlm::tlm_generic_payload& trans){
tlm::tlm_command cmd = trans.get_command();
sc_dt::uint64 adr = trans.get_address();
unsigned char* ptr = trans.get_data_ptr();
unsigned int len = trans.get_data_length();
if(cmd == tlm::TLM_READ_COMMAND){
for(int i = 0; i < len; i++, ptr++)
*ptr = this->mem[adr + i];
}
else if(cmd == tlm::TLM_WRITE_COMMAND){
for(int i = 0; i < len; i++, ptr++)
this->mem[adr + i] = *ptr;
}
return len;
}
// TLM-2 blocking transport method
virtual void b_transport( tlm::tlm_generic_payload& trans, sc_time& delay )
{
tlm::tlm_command cmd = trans.get_command();
sc_dt::uint64 adr = trans.get_address();
unsigned char* ptr = trans.get_data_ptr();
unsigned int len = trans.get_data_length();
unsigned char* byt = trans.get_byte_enable_ptr();
unsigned int wid = trans.get_streaming_width();
// Obliged to check address range and check for unsupported features,
// i.e. byte enables, streaming, and bursts
// Can ignore DMI hint and extensions
// Using the SystemC report handler is an acceptable way of signalling an error
if (adr >= sc_dt::uint64(SIZE) * 4 || adr % 4)
{
trans.set_response_status( tlm::TLM_ADDRESS_ERROR_RESPONSE );
return;
}
else if (byt != 0)
{
trans.set_response_status( tlm::TLM_BYTE_ENABLE_ERROR_RESPONSE );
return;
}
else if (len > 4 || wid < len)
{
trans.set_response_status( tlm::TLM_BURST_ERROR_RESPONSE );
return;
}
// Obliged to implement read and write commands
if ( cmd == tlm::TLM_READ_COMMAND )
memcpy(ptr, &mem[adr/4], len);
else if ( cmd == tlm::TLM_WRITE_COMMAND )
memcpy(&mem[adr/4], ptr, len);
// Obliged to set response status to indicate successful completion
trans.set_response_status( tlm::TLM_OK_RESPONSE );
}
virtual tlm::tlm_sync_enum nb_transport_fw( tlm::tlm_generic_payload& trans,
tlm::tlm_phase& phase, sc_time& delay )
{
sc_dt::uint64 adr = trans.get_address();
unsigned int len = trans.get_data_length();
unsigned char* byt = trans.get_byte_enable_ptr();
unsigned int wid = trans.get_streaming_width();
// Obliged to check the transaction attributes for unsupported features
// and to generate the appropriate error response
if (byt != 0) {
trans.set_response_status( tlm::TLM_BYTE_ENABLE_ERROR_RESPONSE );
return tlm::TLM_COMPLETED;
}
if (len > 4 || wid < len) {
trans.set_response_status( tlm::TLM_BURST_ERROR_RESPONSE );
return tlm::TLM_COMPLETED;
}
// Now queue the transaction until the annotated time has elapsed
m_peq.notify( trans, phase, delay);
return tlm::TLM_ACCEPTED;
}
unsigned int memory::debug
(
tlm::tlm_generic_payload &gp
, sc_core::sc_time &delay_time ///< transaction delay
) {
sc_dt::uint64 address = gp.get_address(); // memory address
tlm::tlm_command command = gp.get_command(); // memory command
unsigned char *data = gp.get_data_ptr(); // data pointer
unsigned int length = gp.get_data_length(); // data length
bool ok = check_address(gp);
if(ok) {
switch (command)
{
case tlm::TLM_WRITE_COMMAND:
for (unsigned int i = 0; i < length; i++) {
m_memory[address++] = data[i]; // move the data to memory
}
gp.set_response_status(tlm::TLM_OK_RESPONSE);
break;
case tlm::TLM_READ_COMMAND:
for (unsigned int i = 0; i < length; i++) {
data[i] = m_memory[address++]; // move the data from memory
}
gp.set_response_status(tlm::TLM_OK_RESPONSE);
break;
default:
ok = 0;
break;
}
} // end switch
return ok ? length : 0;
}
bool IO_t_base::triggerRegistersGotHit(unsigned portIndex, tlm::tlm_generic_payload& trans) {
mb::utl::Segment<uint64_t> transactionRange(trans.get_address(), trans.get_address() + trans.get_data_length());
{
if (0 == portIndex) {
mb::utl::Segment<uint64_t> current((1 + ((0xC % 4) << 3)), (1 + ((0xC % 4) << 3)));
mb::utl::Segment<uint64_t> intersect = transactionRange.intersect(current);
if (!intersect.empty())
return true;
}
}
{
if (0 == portIndex) {
mb::utl::Segment<uint64_t> current((1 + ((0x10 % 4) << 3)), (1 + ((0x10 % 4) << 3)));
mb::utl::Segment<uint64_t> intersect = transactionRange.intersect(current);
if (!intersect.empty())
return true;
}
}
return false;
}
////////////////////////////////////////////////////////////////////////////////////
// Interface function used when receiving a VCI command on the target port
// As the dated transactions on the VCI target port are used to update the local
// time when all DMA channels are IDLE, this component requires periodical
// NULL messages from the interconnect.
////////////////////////////////////////////////////////////////////////////////////
tmpl(tlm::tlm_sync_enum)::nb_transport_fw ( tlm::tlm_generic_payload &payload,
tlm::tlm_phase &phase,
sc_core::sc_time &time)
{
size_t cell;
size_t reg;
size_t channel;
soclib_payload_extension* extension_pointer;
payload.get_extension(extension_pointer);
// Compute global state
bool all_idle = true;
for( size_t k = 0 ; k < m_channels ; k++ )
{
if( m_state[k] != STATE_IDLE ) all_idle = false;
}
// update local time if all channels IDLE
if ( all_idle and (m_pdes_local_time->get().value() < time.value()) )
{
m_pdes_local_time->set( time );
}
// No other action on NULL messages
if ( extension_pointer->is_null_message() )
{
#if SOCLIB_MODULE_DEBUG
std::cout << "[" << name() << "] time = " << time.value()
<< " Receive NULL message" << std::endl;
#endif
return tlm::TLM_COMPLETED;
}
// address and length checking for a VCI command
bool one_flit = (payload.get_data_length() == 4);
addr_t address = payload.get_address();
if ( m_segment.contains(address) && one_flit )
{
cell = (size_t)((address - m_segment.baseAddress()) >> 2);
reg = cell % DMA_SPAN;
channel = cell / DMA_SPAN;
// checking channel overflow
if ( channel < m_channels ) payload.set_response_status(tlm::TLM_OK_RESPONSE);
else payload.set_response_status(tlm::TLM_GENERIC_ERROR_RESPONSE);
if ( extension_pointer->get_command() == VCI_READ_COMMAND )
{
#if SOCLIB_MODULE_DEBUG
std::cout << "[" << name() << "] time = " << time.value()
<< " Receive VCI read command : address = " << std::hex << address
<< " / channel = " << std::dec << channel
<< " / reg = " << reg << std::endl;
#endif
if ( reg == DMA_SRC )
{
utoa( m_source[channel], payload.get_data_ptr(), 0 );
}
else if ( reg == DMA_DST )
{
utoa( m_destination[channel], payload.get_data_ptr(), 0 );
}
else if ( reg == DMA_LEN )
{
utoa( m_state[channel], payload.get_data_ptr(), 0 );
}
else if ( reg == DMA_IRQ_DISABLED )
{
utoa( (int)(m_irq_disabled[channel]), payload.get_data_ptr(), 0 );
}
else payload.set_response_status(tlm::TLM_GENERIC_ERROR_RESPONSE);
} // end read
else if (extension_pointer->get_command() == VCI_WRITE_COMMAND)
{
uint32_t data = atou(payload.get_data_ptr(), 0);
#if SOCLIB_MODULE_DEBUG
std::cout << "[" << name() << "] time = " << time.value()
<< " Receive VCI write command : address = " << std::hex << address
<< " / channel = " << std::dec << channel
<< " / reg = " << reg
<< " / data = " << data << std::endl;
#endif
// configuration command other than soft reset
// are ignored when the DMA channel is active
if ( reg == DMA_RESET )
{
m_stop[channel] = true;
}
else if ( m_state[channel] != STATE_IDLE )
{
if ( reg == DMA_SRC ) m_source[channel] = data;
else if ( reg == DMA_DST ) m_destination[channel] = data;
else if ( reg == DMA_LEN )
{
m_length[channel] = data;
m_stop[channel] = false;
m_event.notify();
}
else if ( cell == DMA_IRQ_DISABLED ) m_irq_disabled[channel] = (data != 0);
else payload.set_response_status(tlm::TLM_GENERIC_ERROR_RESPONSE);
}
else
{
std::cout << name()
<< " warning: receiving a new command while busy, ignored" << std::endl;
}
} // end if write
else // illegal command
{
payload.set_response_status(tlm::TLM_GENERIC_ERROR_RESPONSE);
}
} // end if legal address
bool pl110_t_base::triggerRegistersGotHit(unsigned portIndex, tlm::tlm_generic_payload& trans) {
mb::utl::Segment<uint64_t> transactionRange(trans.get_address(), trans.get_address() + trans.get_data_length());
return false;
}
//=====================================================================
/// @fn dmi_memory::operation
//
/// @brief DMI read and write processing
//
/// @details
/// This routine implements dmi based read and write operations
//
//=====================================================================
void
dmi_memory::operation
( tlm::tlm_generic_payload &gp
, sc_core::sc_time &delay ///< transaction delay
)
{
std::ostringstream msg;
msg.str("");
m_address = gp.get_address();
m_data = gp.get_data_ptr(); ///< data pointer
m_length = gp.get_data_length(); ///< data length
m_command = gp.get_command();
m_is_dmi_flag = false;
gp.set_response_status(tlm::TLM_GENERIC_ERROR_RESPONSE);
if (is_address_dmi(gp) == false )
{
msg << "Iniiator:" << m_ID
<< "A GP with an address not in the allowed DMI ranges has been received"
<< endl << " "
<< "Use check_status before passing a gp to operation";
REPORT_INFO(filename, __FUNCTION__, msg.str());
gp.set_response_status(tlm::TLM_COMMAND_ERROR_RESPONSE); // Need a different error
}
else
{
m_offset = m_address - m_dmi_base_address;
switch (m_command)
{
case tlm::TLM_WRITE_COMMAND:
{
for (unsigned int i = 0; i < m_length; i++)
{
m_dmi_ptr[m_offset + i] = m_data[i];
}
gp.set_response_status(tlm::TLM_OK_RESPONSE);
delay = delay + m_dmi_write_latency; // update time
report::print(m_ID, gp, filename);
break;
}
case tlm::TLM_READ_COMMAND:
{
// clear read buffer
for (unsigned int i = 0; i < m_length; i++)
{
m_data[i] = m_dmi_ptr [m_offset + i];
}
gp.set_response_status(tlm::TLM_OK_RESPONSE);
delay = delay + m_dmi_read_latency; // update time
report::print(m_ID, gp, filename);
break;
}
default:
{
msg << "Target: " << m_ID
<< " Unknown GP command that could be ignorable";
REPORT_WARNING(filename, __FUNCTION__, msg.str());
gp.set_response_status(tlm::TLM_COMMAND_ERROR_RESPONSE);
break;
}
}//end switch
}
return;
//==============================================================================
} // end memory_operation
//==============================================================================
/// @fn memory::operation
//
/// @brief performs read and write
//
/// @details
/// This routine implements the read and write operations. including
/// checking for byte_enable and streaming that are not implemented
//
//==============================================================================
void
memory::operation
( tlm::tlm_generic_payload &gp
, sc_core::sc_time &delay_time ///< transaction delay
)
{
/// Access the required attributes from the payload
sc_dt::uint64 address = gp.get_address(); // memory address
tlm::tlm_command command = gp.get_command(); // memory command
unsigned char *data = gp.get_data_ptr(); // data pointer
unsigned int length = gp.get_data_length(); // data length
std::ostringstream msg;
msg.str("");
tlm::tlm_response_status response_status = check_address(gp);
if (gp.get_byte_enable_ptr())
{
gp.set_response_status(tlm::TLM_BYTE_ENABLE_ERROR_RESPONSE);
}
else if (gp.get_streaming_width() != gp.get_data_length())
{
gp.set_response_status(tlm::TLM_BURST_ERROR_RESPONSE);
}
switch (command)
{
default:
{
if (m_previous_warning == false)
{
msg << "Target: " << m_ID
<< " Unsupported Command Extension";
REPORT_INFO(filename, __FUNCTION__, msg.str());
gp.set_response_status(tlm::TLM_COMMAND_ERROR_RESPONSE);
delay_time = sc_core::SC_ZERO_TIME;
m_previous_warning = true;
}
break;
}
/// Setup a TLM_WRITE_COMMAND Informational Message and Write the Data from
/// the Generic Payload Data pointer to Memory
///
case tlm::TLM_WRITE_COMMAND:
{
if (response_status == tlm::TLM_OK_RESPONSE)
{
for (unsigned int i = 0; i < length; i++)
{
m_memory[address++] = data[i]; // move the data to memory
}
delay_time = delay_time + m_write_delay;
report::print(m_ID, gp, filename);
}
break;
}
case tlm::TLM_READ_COMMAND:
{
if (response_status == tlm::TLM_OK_RESPONSE)
{
for (unsigned int i = 0; i < length; i++)
{
data[i] = m_memory[address++]; // move the data to memory
}
delay_time = delay_time + m_read_delay;
report::print(m_ID, gp, filename);
}
break;
}
} // end switch
gp.set_response_status(response_status);
return;
} // end memory_operation
void peq_cb(tlm::tlm_generic_payload& trans, const tlm::tlm_phase& phase)
{
tlm::tlm_sync_enum status;
sc_time delay;
switch (phase) {
case tlm::BEGIN_REQ:
#ifdef DEBUG
fout << hex << trans.get_address() << " " << name() << " BEGIN_REQ at " << sc_time_stamp() << endl;
#endif
// Increment the transaction reference count
trans.acquire();
// Put back-pressure on initiator by deferring END_REQ until pipeline is clear
if (n_trans == 2)
end_req_pending = &trans;
else
{
status = send_end_req(trans);
if (status == tlm::TLM_COMPLETED) // It is questionable whether this is valid
break;
}
break;
case tlm::END_RESP:
// On receiving END_RESP, the target can release the transaction
// and allow other pending transactions to proceed
#ifdef DEBUG
fout << hex << trans.get_address() << " " << name() << " END_RESP at " << sc_time_stamp() << endl;
#endif
if (!response_in_progress)
SC_REPORT_FATAL("TLM-2", "Illegal transaction phase END_RESP received by target");
trans.release();
n_trans--;
// Target itself is now clear to issue the next BEGIN_RESP
response_in_progress = false;
if (next_response_pending)
{
send_response( *next_response_pending );
next_response_pending = 0;
}
// ... and to unblock the initiator by issuing END_REQ
if (end_req_pending)
{
status = send_end_req( *end_req_pending );
end_req_pending = 0;
}
break;
case tlm::END_REQ:
case tlm::BEGIN_RESP:
SC_REPORT_FATAL("TLM-2", "Illegal transaction phase received by target");
break;
default:
if (phase == internal_ph)
{
// Execute the read or write commands
tlm::tlm_command cmd = trans.get_command();
sc_dt::uint64 adr = trans.get_address();
unsigned char* ptr = trans.get_data_ptr();
unsigned int len = trans.get_data_length();
if ( cmd == tlm::TLM_READ_COMMAND )
{
*reinterpret_cast<int*>(ptr) = rand();
fout << hex << adr << " " << name() << " Execute READ, target = " << name()
<< " data = " << *reinterpret_cast<int*>(ptr) << endl;
}
else if ( cmd == tlm::TLM_WRITE_COMMAND )
fout << hex << adr << " " << name() << " Execute WRITE, target = " << name()
<< " data = " << *reinterpret_cast<int*>(ptr) << endl;
trans.set_response_status( tlm::TLM_OK_RESPONSE );
// Target must honor BEGIN_RESP/END_RESP exclusion rule
// i.e. must not send BEGIN_RESP until receiving previous END_RESP or BEGIN_REQ
if (response_in_progress)
{
// Target allows only two transactions in-flight
if (next_response_pending)
SC_REPORT_FATAL("TLM-2", "Attempt to have two pending responses in target");
next_response_pending = &trans;
}
else
send_response(trans);
break;
}
}
}
tlm::tlm_sync_enum BridgeClassicToAMBATLM2<BUSWIDTH>::nb_bw_transport(tlm::tlm_generic_payload & trans, tlm::tlm_phase & ph, sc_core::sc_time &delay)
{
// std::cout << sc_core::sc_object::name()<< ph << std::endl;
amba::amba_id * m_id;
amba::amba_exclusive * m_exclusive;
tlm::tlm_sync_enum returnVal=tlm::TLM_ACCEPTED;
std::ostringstream msg;
msg.str("");
if(ph == amba::BEGIN_LAST_RESP || ph == tlm::BEGIN_RESP)
{
//assert(trans.get_command()==tlm::TLM_READ_COMMAND && "Write Command doesn't support the response.");
master_sock.template get_extension<amba::amba_id>(m_id,trans);
if (trans.is_write())
{
// std::cout << "TLM BEHAVIOR: received BEGIN_RESP at time " << sc_core::sc_time_stamp() << std::endl;
assert(ph == tlm::BEGIN_RESP);
assert(wr_packets[m_id->value] != NULL);
//as per packet.cc:74 writeback never needs a response
if (wr_packets[m_id->value]->cmd != MemCmd::Writeback)
{
if (master_sock.template get_extension<amba::amba_exclusive>(m_exclusive,trans))
{
if (m_exclusive->value)
{
wr_packets[m_id->value]->req->setExtraData(0);
}
else
{
wr_packets[m_id->value]->req->setExtraData(1);
}
}
setCurTick(sc_core::sc_time_stamp().value());
wr_packets[m_id->value]->busFirstWordDelay = wr_packets[m_id->value]->busLastWordDelay = 0;
if (bus_stalling)
retryQueue.push(wr_packets[m_id->value]);
else if (!slavePort->sendTimingResp(wr_packets[m_id->value]))
{
bus_stalling=true;
retryQueue.push(wr_packets[m_id->value]);
}
#ifdef DEBUG
else if (_trace_transactions)
std::cout << "In " << sc_core::sc_object::name() << " at time " << sc_time_stamp() << " sending a WS response to GEM5 with address=0x" << hex << trans.get_address() << dec << " size=" << trans.get_data_length() << std::endl;
#endif
}
master_sock.release_transaction(&trans); //now we release
wr_packets[m_id->value] = NULL;
if (needWrIdRetry)
{
setCurTick(sc_core::sc_time_stamp().value());
needWrIdRetry=false;
slavePort->sendRetry();
}
}
else if (ph == amba::BEGIN_LAST_RESP)
{
// std::cout << "TLM BEHAVIOR: received BEGIN_LAST_RESP at time " << sc_core::sc_time_stamp() << std::endl;
assert(rd_packets[m_id->value] != NULL);
uint8_t * data=trans.get_data_ptr();
PacketPtr pkt = rd_packets[m_id->value];
pkt->makeTimingResponse();
uint32_t shadow_size=pkt->getSize();
uint64_t shadow_addr=pkt->getAddr();
// std::cout << sc_core::sc_object::name() << " bridge received read data for address = " << trans.get_address()-pkt->getAddr() << " at time " << sc_time_stamp() << std::endl;
memcpy(pkt->getPtr<uint8_t>(),data,pkt->getSize());
// if (master_sock.template get_extension<amba::amba_exclusive>(m_exclusive,trans))
// {
// if (m_exclusive->value)
// pkt->req->setExtraData(0);
// else
// pkt->req->setExtraData(1);
// }
setCurTick(sc_core::sc_time_stamp().value());
pkt->busFirstWordDelay = pkt->busLastWordDelay = 0;
if (bus_stalling)
retryQueue.push(pkt);
else if (!slavePort->sendTimingResp(pkt))
{
bus_stalling=true;
retryQueue.push(pkt);
}
#ifdef DEBUG
else if (_trace_transactions)
{
std::cout << "In " << sc_core::sc_object::name() << " at time " << sc_time_stamp() << " sending a READ response to GEM5 with address=0x" << hex << shadow_addr << dec << " size=" << shadow_size;
std::cout << hex << " and data= [";
for(unsigned j=0;j<shadow_size; j++)
std::cout << "0x" << uint32_t(data[j]) << ",";
std::cout << "]" << dec << std::endl;
}
#endif
rd_packets[m_id->value]=NULL;
master_sock.release_transaction(&trans);
if (needRdIdRetry)
{
setCurTick(sc_core::sc_time_stamp().value());
needRdIdRetry=false;
slavePort->sendRetry();
}
}
else
{
//received a read data phase
}
//always accept directly (cf EagleNest spec)
// std::cout << "TLM BEHAVIOR: sending TLM_UPDATED & END_RESP at time " << sc_core::sc_time_stamp() << std::endl;
ph=tlm::END_RESP;
return tlm::TLM_UPDATED;
}
else if(ph ==tlm::END_REQ)
{
// std::cout << "TLM BEHAVIOR: received END_REQ and returning TLM_ACCEPTED at time " << sc_core::sc_time_stamp() << std::endl;
if (needRetry)
{
setCurTick(sc_core::sc_time_stamp().value());
trans.release();
needRetry=false;
slavePort->sendRetry();
}
}
else if(ph== amba::END_DATA )
{
// std::cout << "TLM BEHAVIOR: received END_DATA and returning TLM_ACCEPTED at time " << sc_core::sc_time_stamp() << std::endl;
if (need_wenable_event)
{
need_wenable_event=false;
wenable_event.notify();
}
return tlm::TLM_ACCEPTED;
}
else
assert("Unexpected phase returned from AXI slave.");
return returnVal;
}
// Instruction interface to functional part of the model
void mmu_cache::exec_instr(tlm::tlm_generic_payload& trans, sc_core::sc_time& delay, bool is_dbg) {
// Vars for payload decoding
tlm::tlm_command cmd = trans.get_command();
sc_dt::uint64 addr = trans.get_address();
unsigned char * ptr = trans.get_data_ptr();
// Log instruction reads for power monitoring
if (m_pow_mon) {
dyn_reads += (trans.get_data_length() >> 2) + 1;
}
// Extract extension
icio_payload_extension * iext;
trans.get_extension(iext);
unsigned int *debug;
unsigned int flush;
// Check/extract instruction payload extension
if (iext!=NULL) {
debug = iext->debug;
flush = iext->flush;
} else {
// No iext
debug = NULL;
flush = 0;
v::error << name() << "IEXT Payload extension missing" << v::endl;
}
// Flush instruction
if (flush) {
v::debug << name() << "Received flush instruction - flushing both caches" << v::endl;
// Simultaneous flush of both caches
icache->flush(&delay, debug, is_dbg);
dcache->flush(&delay, debug, is_dbg);
trans.set_response_status(tlm::TLM_OK_RESPONSE);
return;
}
if (cmd == tlm::TLM_READ_COMMAND) {
assert( 1 ); // fix asi -> priv / unpriv
mmu_cache_base::exec_instr(addr, ptr, 0x8, debug, flush, delay, is_dbg); // ToDo: fix ASI! 0x8 -> unprivileged instruction
// Set response status
trans.set_response_status(tlm::TLM_OK_RESPONSE);
} else {
v::error << name() << " Command not valid for instruction cache (tlm_write)" << v::endl;
// Set response status
trans.set_response_status(tlm::TLM_COMMAND_ERROR_RESPONSE);
}
}