gem5/dev/ide_disk.cc
Andrew Schultz 6807c319b0 Checkin of latest IDE and some separation between platforms (Tsunami and
Turbolaser)

base/range.hh:
    Change semantics of range to be inclusive of the end value, may need to
    check other users of range to make sure they are semantically correct.
    This was needed for access of last byte in range of address on IDE and
    makes sense for case of range from 0 to all f
dev/ide_ctrl.cc:
dev/ide_ctrl.hh:
dev/ide_disk.cc:
dev/ide_disk.hh:
    Whole mess of changes.. at current state simulator will boot and read
    partition table and then have a bunch of errors and panic
dev/pciconfigall.cc:
dev/pciconfigall.hh:
dev/platform.hh:
    Changes to work with platform separation
dev/tsunami.cc:
dev/tsunami.hh:
    Change to work with platform separation

--HG--
extra : convert_revision : e1de22b54df7fdcf391efc2a8555ada93f46beab
2004-05-03 11:47:52 -04:00

871 lines
24 KiB
C++

/*
* Copyright (c) 2003 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.
*/
/** @file
* Device model implementation for an IDE disk
*/
#include <cerrno>
#include <cstring>
#include <deque>
#include <string>
#include "base/cprintf.hh" // csprintf
#include "base/trace.hh"
#include "dev/disk_image.hh"
#include "dev/ide_disk.hh"
#include "dev/ide_ctrl.hh"
#include "dev/tsunami.hh"
#include "dev/tsunami_pchip.hh"
#include "mem/functional_mem/physical_memory.hh"
#include "mem/bus/bus.hh"
#include "mem/bus/dma_interface.hh"
#include "mem/bus/pio_interface.hh"
#include "mem/bus/pio_interface_impl.hh"
#include "sim/builder.hh"
#include "sim/sim_object.hh"
#include "sim/universe.hh"
using namespace std;
IdeDisk::IdeDisk(const string &name, DiskImage *img, PhysicalMemory *phys,
int id, int delay)
: SimObject(name), ctrl(NULL), image(img), physmem(phys), dmaTransferEvent(this),
dmaReadWaitEvent(this), dmaWriteWaitEvent(this), dmaPrdReadEvent(this),
dmaReadEvent(this), dmaWriteEvent(this)
{
diskDelay = (delay * ticksPerSecond / 1000) / image->size();
// initialize the data buffer and shadow registers
dataBuffer = new uint8_t[MAX_DMA_SIZE];
memset(dataBuffer, 0, MAX_DMA_SIZE);
memset(&cmdReg, 0, sizeof(CommandReg_t));
memset(&curPrd.entry, 0, sizeof(PrdEntry_t));
curPrdAddr = 0;
curSector = 0;
curCommand = 0;
cmdBytesLeft = 0;
drqBytesLeft = 0;
dmaRead = false;
intrPending = false;
// fill out the drive ID structure
memset(&driveID, 0, sizeof(struct hd_driveid));
// Calculate LBA and C/H/S values
uint16_t cylinders;
uint8_t heads;
uint8_t sectors;
uint32_t lba_size = image->size();
if (lba_size >= 16383*16*63) {
cylinders = 16383;
heads = 16;
sectors = 63;
} else {
if (lba_size >= 63)
sectors = 63;
else
sectors = lba_size;
if ((lba_size / sectors) >= 16)
heads = 16;
else
heads = (lba_size / sectors);
cylinders = lba_size / (heads * sectors);
}
// Setup the model name
sprintf((char *)driveID.model, "5MI EDD si k");
// Set the maximum multisector transfer size
driveID.max_multsect = MAX_MULTSECT;
// IORDY supported, IORDY disabled, LBA enabled, DMA enabled
driveID.capability = 0x7;
// UDMA support, EIDE support
driveID.field_valid = 0x6;
// Setup default C/H/S settings
driveID.cyls = cylinders;
driveID.sectors = sectors;
driveID.heads = heads;
// Setup the current multisector transfer size
driveID.multsect = MAX_MULTSECT;
driveID.multsect_valid = 0x1;
// Number of sectors on disk
driveID.lba_capacity = lba_size;
// Multiword DMA mode 2 and below supported
driveID.dma_mword = 0x400;
// Set PIO mode 4 and 3 supported
driveID.eide_pio_modes = 0x3;
// Set DMA mode 4 and below supported
driveID.dma_ultra = 0x10;
// Statically set hardware config word
driveID.hw_config = 0x4001;
// set the device state to idle
dmaState = Dma_Idle;
if (id == DEV0) {
devState = Device_Idle_S;
devID = DEV0;
} else if (id == DEV1) {
devState = Device_Idle_NS;
devID = DEV1;
} else {
panic("Invalid device ID: %#x\n", id);
}
// set the device ready bit
cmdReg.status |= STATUS_DRDY_BIT;
}
IdeDisk::~IdeDisk()
{
// destroy the data buffer
delete [] dataBuffer;
}
////
// Device registers read/write
////
void
IdeDisk::read(const Addr &offset, bool byte, bool cmdBlk, uint8_t *data)
{
DevAction_t action = ACT_NONE;
if (cmdBlk) {
if (offset < 0 || offset > sizeof(CommandReg_t))
panic("Invalid disk command register offset: %#x\n", offset);
if (!byte && offset != DATA_OFFSET)
panic("Invalid 16-bit read, only allowed on data reg\n");
if (!byte)
*(uint16_t *)data = *(uint16_t *)&cmdReg.data0;
else
*data = ((uint8_t *)&cmdReg)[offset];
// determine if an action needs to be taken on the state machine
if (offset == STATUS_OFFSET) {
action = ACT_STAT_READ;
} else if (offset == DATA_OFFSET) {
if (byte)
action = ACT_DATA_READ_BYTE;
else
action = ACT_DATA_READ_SHORT;
}
} else {
if (offset != ALTSTAT_OFFSET)
panic("Invalid disk control register offset: %#x\n", offset);
if (!byte)
panic("Invalid 16-bit read from control block\n");
*data = ((uint8_t *)&cmdReg)[STATUS_OFFSET];
}
if (action != ACT_NONE)
updateState(action);
}
void
IdeDisk::write(const Addr &offset, bool byte, bool cmdBlk, const uint8_t *data)
{
DevAction_t action = ACT_NONE;
if (cmdBlk) {
if (offset < 0 || offset > sizeof(CommandReg_t))
panic("Invalid disk command register offset: %#x\n", offset);
if (!byte && offset != DATA_OFFSET)
panic("Invalid 16-bit write, only allowed on data reg\n");
if (!byte)
*((uint16_t *)&cmdReg.data0) = *(uint16_t *)data;
else
((uint8_t *)&cmdReg)[offset] = *data;
// determine if an action needs to be taken on the state machine
if (offset == COMMAND_OFFSET) {
action = ACT_CMD_WRITE;
} else if (offset == DATA_OFFSET) {
if (byte)
action = ACT_DATA_WRITE_BYTE;
else
action = ACT_DATA_WRITE_SHORT;
}
} else {
if (offset != CONTROL_OFFSET)
panic("Invalid disk control register offset: %#x\n", offset);
if (!byte)
panic("Invalid 16-bit write to control block\n");
if (*data & CONTROL_RST_BIT)
panic("Software reset not supported!\n");
nIENBit = (*data & CONTROL_IEN_BIT) ? true : false;
}
if (action != ACT_NONE)
updateState(action);
}
////
// Perform DMA transactions
////
void
IdeDisk::doDmaTransfer()
{
if (dmaState != Dma_Transfer || devState != Transfer_Data_Dma)
panic("Inconsistent DMA transfer state: dmaState = %d devState = %d\n",
dmaState, devState);
// first read the current PRD
if (dmaInterface) {
if (dmaInterface->busy()) {
// reschedule after waiting period
dmaTransferEvent.schedule(curTick + DMA_BACKOFF_PERIOD);
return;
}
dmaInterface->doDMA(Read, curPrdAddr, sizeof(PrdEntry_t), curTick,
&dmaPrdReadEvent);
} else {
dmaPrdReadDone();
}
}
void
IdeDisk::dmaPrdReadDone()
{
// actually copy the PRD from physical memory
memcpy((void *)&curPrd.entry,
physmem->dma_addr(curPrdAddr, sizeof(PrdEntry_t)),
sizeof(PrdEntry_t));
curPrdAddr += sizeof(PrdEntry_t);
if (dmaRead)
doDmaRead();
else
doDmaWrite();
}
void
IdeDisk::doDmaRead()
{
Tick totalDiskDelay = diskDelay * (curPrd.getByteCount() / SectorSize);
if (dmaInterface) {
if (dmaInterface->busy()) {
// reschedule after waiting period
dmaReadWaitEvent.schedule(curTick + DMA_BACKOFF_PERIOD);
return;
}
Addr dmaAddr =
ctrl->tsunami->pchip->translatePciToDma(curPrd.getBaseAddr());
dmaInterface->doDMA(Read, dmaAddr, curPrd.getByteCount(),
curTick + totalDiskDelay, &dmaReadEvent);
} else {
// schedule dmaReadEvent with sectorDelay (dmaReadDone)
dmaReadEvent.schedule(curTick + totalDiskDelay);
}
}
void
IdeDisk::dmaReadDone()
{
// actually copy the data from memory to data buffer
Addr dmaAddr =
ctrl->tsunami->pchip->translatePciToDma(curPrd.getBaseAddr());
memcpy((void *)dataBuffer,
physmem->dma_addr(dmaAddr, curPrd.getByteCount()),
curPrd.getByteCount());
uint32_t bytesWritten = 0;
while (bytesWritten < curPrd.getByteCount()) {
if (cmdBytesLeft <= 0)
panic("DMA data is larger than # sectors specified\n");
writeDisk(curSector++, (uint8_t *)(dataBuffer + bytesWritten));
bytesWritten += SectorSize;
cmdBytesLeft -= SectorSize;
}
// check for the EOT
if (curPrd.getEOT()){
assert(cmdBytesLeft == 0);
dmaState = Dma_Idle;
updateState(ACT_DMA_DONE);
} else {
doDmaTransfer();
}
}
void
IdeDisk::doDmaWrite()
{
Tick totalDiskDelay = diskDelay * (curPrd.getByteCount() / SectorSize);
if (dmaInterface) {
if (dmaInterface->busy()) {
// reschedule after waiting period
dmaWriteWaitEvent.schedule(curTick + DMA_BACKOFF_PERIOD);
return;
}
Addr dmaAddr =
ctrl->tsunami->pchip->translatePciToDma(curPrd.getBaseAddr());
dmaInterface->doDMA(WriteInvalidate, dmaAddr,
curPrd.getByteCount(), curTick + totalDiskDelay,
&dmaWriteEvent);
} else {
// schedule event with disk delay (dmaWriteDone)
dmaWriteEvent.schedule(curTick + totalDiskDelay);
}
}
void
IdeDisk::dmaWriteDone()
{
uint32_t bytesRead = 0;
// clear out the data buffer
memset(dataBuffer, 0, MAX_DMA_SIZE);
while (bytesRead < curPrd.getByteCount()) {
if (cmdBytesLeft <= 0)
panic("DMA requested data is larger than # sectors specified\n");
readDisk(curSector++, (uint8_t *)(dataBuffer + bytesRead));
bytesRead += SectorSize;
cmdBytesLeft -= SectorSize;
}
// copy the data to memory
Addr dmaAddr =
ctrl->tsunami->pchip->translatePciToDma(curPrd.getBaseAddr());
memcpy(physmem->dma_addr(dmaAddr, curPrd.getByteCount()),
(void *)dataBuffer, curPrd.getByteCount());
// check for the EOT
if (curPrd.getEOT()) {
assert(cmdBytesLeft == 0);
dmaState = Dma_Idle;
updateState(ACT_DMA_DONE);
} else {
doDmaTransfer();
}
}
////
// Disk utility routines
///
void
IdeDisk::readDisk(uint32_t sector, uint8_t *data)
{
uint32_t bytesRead = image->read(data, sector);
if (bytesRead != SectorSize)
panic("Can't read from %s. Only %d of %d read. errno=%d\n",
name(), bytesRead, SectorSize, errno);
}
void
IdeDisk::writeDisk(uint32_t sector, uint8_t *data)
{
uint32_t bytesWritten = image->write(data, sector);
if (bytesWritten != SectorSize)
panic("Can't write to %s. Only %d of %d written. errno=%d\n",
name(), bytesWritten, SectorSize, errno);
}
////
// Setup and handle commands
////
void
IdeDisk::startDma(const uint32_t &prdTableBase)
{
if (dmaState != Dma_Start)
panic("Inconsistent DMA state, should be in Dma_Start!\n");
if (devState != Transfer_Data_Dma)
panic("Inconsistent device state for DMA start!\n");
curPrdAddr = ctrl->tsunami->pchip->translatePciToDma(prdTableBase);
dmaState = Dma_Transfer;
// schedule dma transfer (doDmaTransfer)
dmaTransferEvent.schedule(curTick + 1);
}
void
IdeDisk::abortDma()
{
if (dmaState == Dma_Idle)
panic("Inconsistent DMA state, should be in Dma_Start or Dma_Transfer!\n");
if (devState != Transfer_Data_Dma && devState != Prepare_Data_Dma)
panic("Inconsistent device state, should be in Transfer or Prepare!\n");
updateState(ACT_CMD_ERROR);
}
void
IdeDisk::startCommand()
{
DevAction_t action = ACT_NONE;
uint32_t size = 0;
dmaRead = false;
// copy the command to the shadow
curCommand = cmdReg.command;
// Decode commands
switch (cmdReg.command) {
// Supported non-data commands
case WIN_READ_NATIVE_MAX:
size = image->size() - 1;
cmdReg.sec_num = (size & 0xff);
cmdReg.cyl_low = ((size & 0xff00) >> 8);
cmdReg.cyl_high = ((size & 0xff0000) >> 16);
cmdReg.head = ((size & 0xf000000) >> 24);
devState = Command_Execution;
action = ACT_CMD_COMPLETE;
break;
case WIN_RECAL:
case WIN_SPECIFY:
case WIN_FLUSH_CACHE:
case WIN_VERIFY:
case WIN_SEEK:
case WIN_SETFEATURES:
case WIN_SETMULT:
devState = Command_Execution;
action = ACT_CMD_COMPLETE;
break;
// Supported PIO data-in commands
case WIN_IDENTIFY:
cmdBytesLeft = drqBytesLeft = sizeof(struct hd_driveid);
devState = Prepare_Data_In;
action = ACT_DATA_READY;
break;
case WIN_MULTREAD:
case WIN_READ:
if (!(cmdReg.drive & DRIVE_LBA_BIT))
panic("Attempt to perform CHS access, only supports LBA\n");
if (cmdReg.sec_count == 0)
cmdBytesLeft = (256 * SectorSize);
else
cmdBytesLeft = (cmdReg.sec_count * SectorSize);
drqBytesLeft = SectorSize;
curSector = getLBABase();
devState = Prepare_Data_In;
action = ACT_DATA_READY;
break;
// Supported PIO data-out commands
case WIN_MULTWRITE:
case WIN_WRITE:
if (!(cmdReg.drive & DRIVE_LBA_BIT))
panic("Attempt to perform CHS access, only supports LBA\n");
if (cmdReg.sec_count == 0)
cmdBytesLeft = (256 * SectorSize);
else
cmdBytesLeft = (cmdReg.sec_count * SectorSize);
drqBytesLeft = SectorSize;
curSector = getLBABase();
devState = Prepare_Data_Out;
action = ACT_DATA_READY;
break;
// Supported DMA commands
case WIN_WRITEDMA:
dmaRead = true; // a write to the disk is a DMA read from memory
case WIN_READDMA:
if (!(cmdReg.drive & DRIVE_LBA_BIT))
panic("Attempt to perform CHS access, only supports LBA\n");
if (cmdReg.sec_count == 0)
cmdBytesLeft = (256 * SectorSize);
else
cmdBytesLeft = (cmdReg.sec_count * SectorSize);
drqBytesLeft = SectorSize;
curSector = getLBABase();
devState = Prepare_Data_Dma;
action = ACT_DMA_READY;
break;
default:
panic("Unsupported ATA command: %#x\n", cmdReg.command);
}
if (action != ACT_NONE) {
// set the BSY bit
cmdReg.status |= STATUS_BSY_BIT;
// clear the DRQ bit
cmdReg.status &= ~STATUS_DRQ_BIT;
updateState(action);
}
}
////
// Handle setting and clearing interrupts
////
void
IdeDisk::intrPost()
{
if (intrPending)
panic("Attempt to post an interrupt with one pending\n");
intrPending = true;
// talk to controller to set interrupt
if (ctrl)
ctrl->intrPost();
}
void
IdeDisk::intrClear()
{
if (!intrPending)
panic("Attempt to clear a non-pending interrupt\n");
intrPending = false;
// talk to controller to clear interrupt
if (ctrl)
ctrl->intrClear();
}
////
// Manage the device internal state machine
////
void
IdeDisk::updateState(DevAction_t action)
{
switch (devState) {
case Device_Idle_S:
if (!isDEVSelect())
devState = Device_Idle_NS;
else if (action == ACT_CMD_WRITE)
startCommand();
break;
case Device_Idle_SI:
if (!isDEVSelect()) {
devState = Device_Idle_NS;
intrClear();
} else if (action == ACT_STAT_READ || isIENSet()) {
devState = Device_Idle_S;
intrClear();
} else if (action == ACT_CMD_WRITE) {
intrClear();
startCommand();
}
break;
case Device_Idle_NS:
if (isDEVSelect()) {
if (!isIENSet() && intrPending) {
devState = Device_Idle_SI;
intrPost();
}
if (isIENSet() || !intrPending) {
devState = Device_Idle_S;
}
}
break;
case Command_Execution:
if (action == ACT_CMD_COMPLETE) {
// clear the BSY bit
setComplete();
if (!isIENSet()) {
devState = Device_Idle_SI;
intrPost();
} else {
devState = Device_Idle_S;
}
}
break;
case Prepare_Data_In:
if (action == ACT_CMD_ERROR) {
// clear the BSY bit
setComplete();
if (!isIENSet()) {
devState = Device_Idle_SI;
intrPost();
} else {
devState = Device_Idle_S;
}
} else if (action == ACT_DATA_READY) {
// clear the BSY bit
cmdReg.status &= ~STATUS_BSY_BIT;
// set the DRQ bit
cmdReg.status |= STATUS_DRQ_BIT;
// put the first two bytes into the data register
memcpy((void *)&cmdReg.data0, (void *)dataBuffer, sizeof(uint16_t));
// copy the data into the data buffer
if (curCommand == WIN_IDENTIFY)
memcpy((void *)dataBuffer, (void *)&driveID,
sizeof(struct hd_driveid));
else
readDisk(curSector++, dataBuffer);
if (!isIENSet()) {
devState = Data_Ready_INTRQ_In;
intrPost();
} else {
devState = Transfer_Data_In;
}
}
break;
case Data_Ready_INTRQ_In:
if (action == ACT_STAT_READ) {
devState = Transfer_Data_In;
intrClear();
}
break;
case Transfer_Data_In:
if (action == ACT_DATA_READ_BYTE || action == ACT_DATA_READ_SHORT) {
if (action == ACT_DATA_READ_BYTE) {
panic("DEBUG: READING DATA ONE BYTE AT A TIME!\n");
} else {
drqBytesLeft -= 2;
cmdBytesLeft -= 2;
// copy next short into data registers
memcpy((void *)&cmdReg.data0,
(void *)&dataBuffer[SectorSize - drqBytesLeft],
sizeof(uint16_t));
}
if (drqBytesLeft == 0) {
if (cmdBytesLeft == 0) {
// Clear the BSY bit
setComplete();
devState = Device_Idle_S;
} else {
devState = Prepare_Data_In;
cmdReg.status |= STATUS_BSY_BIT;
}
}
}
break;
case Prepare_Data_Out:
if (action == ACT_CMD_ERROR || cmdBytesLeft == 0) {
// clear the BSY bit
setComplete();
if (!isIENSet()) {
devState = Device_Idle_SI;
intrPost();
} else {
devState = Device_Idle_S;
}
} else if (cmdBytesLeft != 0) {
// clear the BSY bit
cmdReg.status &= ~STATUS_BSY_BIT;
// set the DRQ bit
cmdReg.status |= STATUS_DRQ_BIT;
// clear the data buffer to get it ready for writes
memset(dataBuffer, 0, MAX_DMA_SIZE);
if (!isIENSet()) {
devState = Data_Ready_INTRQ_Out;
intrPost();
} else {
devState = Transfer_Data_Out;
}
}
break;
case Data_Ready_INTRQ_Out:
if (action == ACT_STAT_READ) {
devState = Transfer_Data_Out;
intrClear();
}
break;
case Transfer_Data_Out:
if (action == ACT_DATA_WRITE_BYTE || action == ACT_DATA_WRITE_SHORT) {
if (action == ACT_DATA_READ_BYTE) {
panic("DEBUG: WRITING DATA ONE BYTE AT A TIME!\n");
} else {
// copy the latest short into the data buffer
memcpy((void *)&dataBuffer[SectorSize - drqBytesLeft],
(void *)&cmdReg.data0,
sizeof(uint16_t));
drqBytesLeft -= 2;
cmdBytesLeft -= 2;
}
if (drqBytesLeft == 0) {
// copy the block to the disk
writeDisk(curSector++, dataBuffer);
// set the BSY bit
cmdReg.status |= STATUS_BSY_BIT;
// clear the DRQ bit
cmdReg.status &= ~STATUS_DRQ_BIT;
devState = Prepare_Data_Out;
}
}
break;
case Prepare_Data_Dma:
if (action == ACT_CMD_ERROR) {
// clear the BSY bit
setComplete();
if (!isIENSet()) {
devState = Device_Idle_SI;
intrPost();
} else {
devState = Device_Idle_S;
}
} else if (action == ACT_DMA_READY) {
// clear the BSY bit
cmdReg.status &= ~STATUS_BSY_BIT;
// set the DRQ bit
cmdReg.status |= STATUS_DRQ_BIT;
devState = Transfer_Data_Dma;
if (dmaState != Dma_Idle)
panic("Inconsistent DMA state, should be Dma_Idle\n");
dmaState = Dma_Start;
// wait for the write to the DMA start bit
}
break;
case Transfer_Data_Dma:
if (action == ACT_CMD_ERROR || action == ACT_DMA_DONE) {
// clear the BSY bit
setComplete();
// set the seek bit
cmdReg.status |= 0x10;
// clear the controller state for DMA transfer
ctrl->setDmaComplete(this);
if (!isIENSet()) {
devState = Device_Idle_SI;
intrPost();
} else {
devState = Device_Idle_S;
}
}
break;
default:
panic("Unknown IDE device state: %#x\n", devState);
}
}
void
IdeDisk::serialize(ostream &os)
{
}
void
IdeDisk::unserialize(Checkpoint *cp, const string &section)
{
}
#ifndef DOXYGEN_SHOULD_SKIP_THIS
BEGIN_DECLARE_SIM_OBJECT_PARAMS(IdeDisk)
SimObjectParam<DiskImage *> image;
SimObjectParam<PhysicalMemory *> physmem;
Param<int> driveID;
Param<int> disk_delay;
END_DECLARE_SIM_OBJECT_PARAMS(IdeDisk)
BEGIN_INIT_SIM_OBJECT_PARAMS(IdeDisk)
INIT_PARAM(image, "Disk image"),
INIT_PARAM(physmem, "Physical memory"),
INIT_PARAM(driveID, "Drive ID (0=master 1=slave)"),
INIT_PARAM_DFLT(disk_delay, "Fixed disk delay in milliseconds", 0)
END_INIT_SIM_OBJECT_PARAMS(IdeDisk)
CREATE_SIM_OBJECT(IdeDisk)
{
return new IdeDisk(getInstanceName(), image, physmem, driveID, disk_delay);
}
REGISTER_SIM_OBJECT("IdeDisk", IdeDisk)
#endif //DOXYGEN_SHOULD_SKIP_THIS