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/*
* Copyright (c) 2006 The Regents of The University of Michigan
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met: redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer;
* 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;
* neither the name of the copyright holders 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
* OWNER 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.
*
* Authors: Ali Saidi
*/
/* @file
* Device model for Intel's 8254x line of gigabit ethernet controllers.
* In particular an 82547 revision 2 (82547GI) MAC because it seems to have the
* fewest workarounds in the driver. It will probably work with most of the
* other MACs with slight modifications.
*/
#include "base/inet.hh"
#include "dev/i8254xGBe.hh"
#include "mem/packet.hh"
#include "mem/packet_access.hh"
#include "sim/builder.hh"
#include "sim/stats.hh"
#include "sim/system.hh"
using namespace iGbReg;
IGbE::IGbE(Params *p)
: PciDev(p), etherInt(NULL), useFlowControl(p->use_flow_control)
{
// Initialized internal registers per Intel documentation
regs.tctl(0);
regs.rctl(0);
regs.ctrl(0);
regs.ctrl.fd(1);
regs.ctrl.lrst(1);
regs.ctrl.speed(2);
regs.ctrl.frcspd(1);
regs.sts(0);
regs.sts.speed(3); // Say we're 1000Mbps
regs.sts.fd(1); // full duplex
regs.eecd(0);
regs.eecd.fwe(1);
regs.eecd.ee_type(1);
regs.eerd(0);
regs.icr(0);
regs.rctl(0);
regs.tctl(0);
regs.fcrtl(0);
regs.fcrth(1);
regs.manc(0);
regs.pba.rxa(0x30);
regs.pba.txa(0x10);
eeOpBits = 0;
eeAddrBits = 0;
eeDataBits = 0;
eeOpcode = 0;
// clear all 64 16 bit words of the eeprom
memset(&flash, 0, EEPROM_SIZE*2);
//We'll need to instert the MAC address into the flash
flash[0] = 0xA4A4;
flash[1] = 0xB6B6;
flash[2] = 0xC8C8;
uint16_t csum = 0;
for (int x = 0; x < EEPROM_SIZE; x++)
csum += flash[x];
// Magic happy checksum value
flash[EEPROM_SIZE-1] = htobe((uint16_t)(EEPROM_CSUM - csum));
}
Tick
IGbE::writeConfig(PacketPtr pkt)
{
int offset = pkt->getAddr() & PCI_CONFIG_SIZE;
if (offset < PCI_DEVICE_SPECIFIC)
PciDev::writeConfig(pkt);
else
panic("Device specific PCI config space not implemented.\n");
///
/// Some work may need to be done here based for the pci COMMAND bits.
///
return pioDelay;
}
Tick
IGbE::read(PacketPtr pkt)
{
int bar;
Addr daddr;
if (!getBAR(pkt->getAddr(), bar, daddr))
panic("Invalid PCI memory access to unmapped memory.\n");
// Only Memory register BAR is allowed
assert(bar == 0);
// Only 32bit accesses allowed
assert(pkt->getSize() == 4);
//DPRINTF(Ethernet, "Read device register %#X\n", daddr);
pkt->allocate();
///
/// Handle read of register here
///
switch (daddr) {
case REG_CTRL:
pkt->set<uint32_t>(regs.ctrl());
break;
case REG_STATUS:
pkt->set<uint32_t>(regs.sts());
break;
case REG_EECD:
pkt->set<uint32_t>(regs.eecd());
break;
case REG_EERD:
pkt->set<uint32_t>(regs.eerd());
break;
case REG_CTRL_EXT:
pkt->set<uint32_t>(regs.ctrl_ext());
break;
case REG_MDIC:
pkt->set<uint32_t>(regs.mdic());
break;
case REG_ICR:
pkt->set<uint32_t>(regs.icr());
// handle auto setting mask from IAM
break;
case REG_ITR:
pkt->set<uint32_t>(regs.itr());
break;
case REG_RCTL:
pkt->set<uint32_t>(regs.rctl());
break;
case REG_FCTTV:
pkt->set<uint32_t>(regs.fcttv());
break;
case REG_TCTL:
pkt->set<uint32_t>(regs.tctl());
break;
case REG_PBA:
pkt->set<uint32_t>(regs.pba());
break;
case REG_WUC:
case REG_LEDCTL:
pkt->set<uint32_t>(0); // We don't care, so just return 0
break;
case REG_FCRTL:
pkt->set<uint32_t>(regs.fcrtl());
break;
case REG_FCRTH:
pkt->set<uint32_t>(regs.fcrth());
break;
case REG_RDBAL:
pkt->set<uint32_t>(regs.rdba.rdbal());
break;
case REG_RDBAH:
pkt->set<uint32_t>(regs.rdba.rdbah());
break;
case REG_RDLEN:
pkt->set<uint32_t>(regs.rdlen());
break;
case REG_RDH:
pkt->set<uint32_t>(regs.rdh());
break;
case REG_RDT:
pkt->set<uint32_t>(regs.rdt());
break;
case REG_RDTR:
pkt->set<uint32_t>(regs.rdtr());
break;
case REG_RADV:
pkt->set<uint32_t>(regs.radv());
break;
case REG_TDBAL:
pkt->set<uint32_t>(regs.tdba.tdbal());
break;
case REG_TDBAH:
pkt->set<uint32_t>(regs.tdba.tdbah());
break;
case REG_TDLEN:
pkt->set<uint32_t>(regs.tdlen());
break;
case REG_TDH:
pkt->set<uint32_t>(regs.tdh());
break;
case REG_TDT:
pkt->set<uint32_t>(regs.tdt());
break;
case REG_TIDV:
pkt->set<uint32_t>(regs.tidv());
break;
case REG_TXDCTL:
pkt->set<uint32_t>(regs.txdctl());
break;
case REG_TADV:
pkt->set<uint32_t>(regs.tadv());
break;
case REG_RXCSUM:
pkt->set<uint32_t>(regs.rxcsum());
break;
case REG_MANC:
pkt->set<uint32_t>(regs.manc());
break;
default:
if (!(daddr >= REG_VFTA && daddr < (REG_VFTA + VLAN_FILTER_TABLE_SIZE*4)) &&
!(daddr >= REG_RAL && daddr < (REG_RAL + RCV_ADDRESS_TABLE_SIZE*8)) &&
!(daddr >= REG_MTA && daddr < (REG_MTA + MULTICAST_TABLE_SIZE*4)) &&
!(daddr >= REG_CRCERRS && daddr < (REG_CRCERRS + STATS_REGS_SIZE)))
panic("Read request to unknown register number: %#x\n", daddr);
else
pkt->set<uint32_t>(0);
};
pkt->result = Packet::Success;
return pioDelay;
}
Tick
IGbE::write(PacketPtr pkt)
{
int bar;
Addr daddr;
if (!getBAR(pkt->getAddr(), bar, daddr))
panic("Invalid PCI memory access to unmapped memory.\n");
// Only Memory register BAR is allowed
assert(bar == 0);
// Only 32bit accesses allowed
assert(pkt->getSize() == sizeof(uint32_t));
//DPRINTF(Ethernet, "Wrote device register %#X value %#X\n", daddr, pkt->get<uint32_t>());
///
/// Handle write of register here
///
uint32_t val = pkt->get<uint32_t>();
switch (daddr) {
case REG_CTRL:
regs.ctrl = val;
if (regs.ctrl.tfce())
warn("TX Flow control enabled, should implement\n");
if (regs.ctrl.rfce())
warn("RX Flow control enabled, should implement\n");
break;
case REG_CTRL_EXT:
regs.ctrl_ext = val;
break;
case REG_STATUS:
regs.sts = val;
break;
case REG_EECD:
int oldClk;
oldClk = regs.eecd.sk();
regs.eecd = val;
// See if this is a eeprom access and emulate accordingly
if (!oldClk && regs.eecd.sk()) {
if (eeOpBits < 8) {
eeOpcode = eeOpcode << 1 | regs.eecd.din();
eeOpBits++;
} else if (eeAddrBits < 8 && eeOpcode == EEPROM_READ_OPCODE_SPI) {
eeAddr = eeAddr << 1 | regs.eecd.din();
eeAddrBits++;
} else if (eeDataBits < 16 && eeOpcode == EEPROM_READ_OPCODE_SPI) {
assert(eeAddr>>1 < EEPROM_SIZE);
DPRINTF(EthernetEEPROM, "EEPROM bit read: %d word: %#X\n",
flash[eeAddr>>1] >> eeDataBits & 0x1, flash[eeAddr>>1]);
regs.eecd.dout((flash[eeAddr>>1] >> (15-eeDataBits)) & 0x1);
eeDataBits++;
} else if (eeDataBits < 8 && eeOpcode == EEPROM_RDSR_OPCODE_SPI) {
regs.eecd.dout(0);
eeDataBits++;
} else
panic("What's going on with eeprom interface? opcode:"
" %#x:%d addr: %#x:%d, data: %d\n", (uint32_t)eeOpcode,
(uint32_t)eeOpBits, (uint32_t)eeAddr,
(uint32_t)eeAddrBits, (uint32_t)eeDataBits);
// Reset everything for the next command
if ((eeDataBits == 16 && eeOpcode == EEPROM_READ_OPCODE_SPI) ||
(eeDataBits == 8 && eeOpcode == EEPROM_RDSR_OPCODE_SPI)) {
eeOpBits = 0;
eeAddrBits = 0;
eeDataBits = 0;
eeOpcode = 0;
eeAddr = 0;
}
DPRINTF(EthernetEEPROM, "EEPROM: opcode: %#X:%d addr: %#X:%d\n",
(uint32_t)eeOpcode, (uint32_t) eeOpBits,
(uint32_t)eeAddr>>1, (uint32_t)eeAddrBits);
if (eeOpBits == 8 && !(eeOpcode == EEPROM_READ_OPCODE_SPI ||
eeOpcode == EEPROM_RDSR_OPCODE_SPI ))
panic("Unknown eeprom opcode: %#X:%d\n", (uint32_t)eeOpcode,
(uint32_t)eeOpBits);
}
// If driver requests eeprom access, immediately give it to it
regs.eecd.ee_gnt(regs.eecd.ee_req());
break;
case REG_EERD:
regs.eerd = val;
break;
case REG_MDIC:
regs.mdic = val;
if (regs.mdic.i())
panic("No support for interrupt on mdic complete\n");
if (regs.mdic.phyadd() != 1)
panic("No support for reading anything but phy\n");
DPRINTF(Ethernet, "%s phy address %x\n", regs.mdic.op() == 1 ? "Writing"
: "Reading", regs.mdic.regadd());
switch (regs.mdic.regadd()) {
case PHY_PSTATUS:
regs.mdic.data(0x796D); // link up
break;
case PHY_PID:
regs.mdic.data(0x02A8);
break;
case PHY_EPID:
regs.mdic.data(0x0380);
break;
case PHY_GSTATUS:
regs.mdic.data(0x7C00);
break;
case PHY_EPSTATUS:
regs.mdic.data(0x3000);
break;
case PHY_AGC:
regs.mdic.data(0x180); // some random length
break;
default:
regs.mdic.data(0);
warn("Accessing unknown phy register %d\n", regs.mdic.regadd());
}
regs.mdic.r(1);
break;
case REG_ICR:
regs.icr = val;
// handle auto setting mask from IAM
break;
case REG_ITR:
regs.itr = val;
break;
case REG_ICS:
regs.icr = val | regs.icr();
// generate an interrupt if needed here
break;
case REG_IMS:
regs.imr |= val;
// handle interrupts if needed here
break;
case REG_IMC:
regs.imr |= ~val;
// handle interrupts if needed here
break;
case REG_IAM:
regs.iam = val;
break;
case REG_RCTL:
regs.rctl = val;
break;
case REG_FCTTV:
regs.fcttv = val;
break;
case REG_TCTL:
regs.tctl = val;
break;
case REG_PBA:
regs.pba.rxa(val);
regs.pba.txa(64 - regs.pba.rxa());
break;
case REG_WUC:
case REG_LEDCTL:
case REG_FCAL:
case REG_FCAH:
case REG_FCT:
case REG_VET:
case REG_AIFS:
case REG_TIPG:
; // We don't care, so don't store anything
break;
case REG_FCRTL:
regs.fcrtl = val;
break;
case REG_FCRTH:
regs.fcrth = val;
break;
case REG_RDBAL:
regs.rdba.rdbal( val & ~mask(4));
break;
case REG_RDBAH:
regs.rdba.rdbah(val);
break;
case REG_RDLEN:
regs.rdlen = val & ~mask(7);
break;
case REG_RDH:
regs.rdh = val;
break;
case REG_RDT:
regs.rdt = val;
break;
case REG_RDTR:
regs.rdtr = val;
break;
case REG_RADV:
regs.radv = val;
break;
case REG_TDBAL:
regs.tdba.tdbal( val & ~mask(4));
break;
case REG_TDBAH:
regs.tdba.tdbah(val);
break;
case REG_TDLEN:
regs.tdlen = val & ~mask(7);
break;
case REG_TDH:
regs.tdh = val;
break;
case REG_TDT:
regs.tdt = val;
break;
case REG_TIDV:
regs.tidv = val;
break;
case REG_TXDCTL:
regs.txdctl = val;
break;
case REG_TADV:
regs.tadv = val;
break;
case REG_RXCSUM:
regs.rxcsum = val;
break;
case REG_MANC:
regs.manc = val;
break;
default:
if (!(daddr >= REG_VFTA && daddr < (REG_VFTA + VLAN_FILTER_TABLE_SIZE*4)) &&
!(daddr >= REG_RAL && daddr < (REG_RAL + RCV_ADDRESS_TABLE_SIZE*8)) &&
!(daddr >= REG_MTA && daddr < (REG_MTA + MULTICAST_TABLE_SIZE*4)))
panic("Write request to unknown register number: %#x\n", daddr);
};
pkt->result = Packet::Success;
return pioDelay;
}
bool
IGbE::ethRxPkt(EthPacketPtr packet)
{
panic("Need to implemenet\n");
}
void
IGbE::ethTxDone()
{
panic("Need to implemenet\n");
}
void
IGbE::serialize(std::ostream &os)
{
panic("Need to implemenet\n");
}
void
IGbE::unserialize(Checkpoint *cp, const std::string §ion)
{
panic("Need to implemenet\n");
}
BEGIN_DECLARE_SIM_OBJECT_PARAMS(IGbEInt)
SimObjectParam<EtherInt *> peer;
SimObjectParam<IGbE *> device;
END_DECLARE_SIM_OBJECT_PARAMS(IGbEInt)
BEGIN_INIT_SIM_OBJECT_PARAMS(IGbEInt)
INIT_PARAM_DFLT(peer, "peer interface", NULL),
INIT_PARAM(device, "Ethernet device of this interface")
END_INIT_SIM_OBJECT_PARAMS(IGbEInt)
CREATE_SIM_OBJECT(IGbEInt)
{
IGbEInt *dev_int = new IGbEInt(getInstanceName(), device);
EtherInt *p = (EtherInt *)peer;
if (p) {
dev_int->setPeer(p);
p->setPeer(dev_int);
}
return dev_int;
}
REGISTER_SIM_OBJECT("IGbEInt", IGbEInt)
BEGIN_DECLARE_SIM_OBJECT_PARAMS(IGbE)
SimObjectParam<System *> system;
SimObjectParam<Platform *> platform;
SimObjectParam<PciConfigData *> configdata;
Param<uint32_t> pci_bus;
Param<uint32_t> pci_dev;
Param<uint32_t> pci_func;
Param<Tick> pio_latency;
Param<Tick> config_latency;
END_DECLARE_SIM_OBJECT_PARAMS(IGbE)
BEGIN_INIT_SIM_OBJECT_PARAMS(IGbE)
INIT_PARAM(system, "System pointer"),
INIT_PARAM(platform, "Platform pointer"),
INIT_PARAM(configdata, "PCI Config data"),
INIT_PARAM(pci_bus, "PCI bus ID"),
INIT_PARAM(pci_dev, "PCI device number"),
INIT_PARAM(pci_func, "PCI function code"),
INIT_PARAM_DFLT(pio_latency, "Programmed IO latency in bus cycles", 1),
INIT_PARAM(config_latency, "Number of cycles for a config read or write")
END_INIT_SIM_OBJECT_PARAMS(IGbE)
CREATE_SIM_OBJECT(IGbE)
{
IGbE::Params *params = new IGbE::Params;
params->name = getInstanceName();
params->platform = platform;
params->system = system;
params->configData = configdata;
params->busNum = pci_bus;
params->deviceNum = pci_dev;
params->functionNum = pci_func;
params->pio_delay = pio_latency;
params->config_delay = config_latency;
return new IGbE(params);
}
REGISTER_SIM_OBJECT("IGbE", IGbE)
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