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RealtekR1000SL.cpp
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RealtekR1000SL.cpp
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/*
* RealtekR1000SL.cpp - OS specific and hardware generic methods
* RealtekR1000SL
*
* Copyright 2009 Chuck Fry. All rights reserved.
*
* This software incorporates code from Realtek's open source Linux drivers
* and the open source Mac OS X project RealtekR1000 by Dmitri Arekhta,
* as modified by PSYSTAR Corporation.
*
* Copyright(c) 2009 Realtek Semiconductor Corp. All rights reserved.
* copyright PSYSTAR Corporation, 2008
* 2006 (c) Dmitri Arekhta (DaemonES@gmail.com)
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*/
#include "RealtekR1000SL.h"
#include "impl_defs.h"
#define BaseClass IOEthernetController
OSDefineMetaClassAndStructors(RealtekR1000, IOEthernetController)
// **********************************
//
// Static Data Member Initialization
//
// **********************************
//
// Configuration data
//
//
// *** N.B.: The order of these entries MUST match
// *** the enum mcfg_methods in R1000Regs.h!!
//
const struct RtlChipInfo RealtekR1000::rtl_chip_info[] =
{
//
// RTL810x Family
//
{"RTL8100E",
MCFG_8100E_1,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8100E",
MCFG_8100E_2,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8101E",
MCFG_8101E_1,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8101E",
MCFG_8101E_2,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8101E",
MCFG_8101E_3,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8102E",
MCFG_8102E_1,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8102E",
MCFG_8102E_2,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8103E",
MCFG_8103E_1,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8103E",
MCFG_8103E_2,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8103E",
MCFG_8103E_3,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8105E",
MCFG_8105E_1,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8105E",
MCFG_8105E_2,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8105E",
MCFG_8105E_3,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8105E",
MCFG_8105E_4,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
//
// RTL8168/8111 Family
//
{"RTL8168B/8111B",
MCFG_8168B_1,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_4k,
EFUSE_NOT_SUPPORT},
{"RTL8168B/8111B",
MCFG_8168B_2,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_4k,
EFUSE_NOT_SUPPORT},
{"RTL8168B/8111B",
MCFG_8168B_3,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_4k,
EFUSE_NOT_SUPPORT},
{"RTL8168C/8111C",
MCFG_8168C_1,
1024,
RxCfg_128_int_en | RxCfg_fet_multi_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_6k,
EFUSE_NOT_SUPPORT},
{"RTL8168C/8111C",
MCFG_8168C_2,
1024,
RxCfg_128_int_en | RxCfg_fet_multi_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_6k,
EFUSE_NOT_SUPPORT},
{"RTL8168C/8111C",
MCFG_8168C_3,
1024,
RxCfg_128_int_en | RxCfg_fet_multi_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_6k,
EFUSE_NOT_SUPPORT},
{"RTL8168CP/8111CP",
MCFG_8168CP_1,
1024,
RxCfg_128_int_en | RxCfg_fet_multi_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_6k,
EFUSE_NOT_SUPPORT},
{"RTL8168CP/8111CP",
MCFG_8168CP_2,
1024,
RxCfg_128_int_en | RxCfg_fet_multi_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_6k,
EFUSE_NOT_SUPPORT},
{"RTL8168D/8111D",
MCFG_8168D_1,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k,
EFUSE_SUPPORT},
{"RTL8168D/8111D",
MCFG_8168D_2,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k,
EFUSE_SUPPORT},
{"RTL8168DP/8111DP",
MCFG_8168DP_1,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k,
EFUSE_SUPPORT},
{"RTL8168DP/8111DP",
MCFG_8168DP_2,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k,
EFUSE_SUPPORT},
{"RTL8168DP/8111DP",
MCFG_8168DP_3,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k,
EFUSE_SUPPORT},
{"RTL8168E/8111E",
MCFG_8168E_1,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k,
EFUSE_SUPPORT},
{"RTL8168E/8111E",
MCFG_8168E_2,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k,
EFUSE_SUPPORT},
{"RTL8168E-VL/8111E-VL",
MCFG_8168E_VL_1,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k,
EFUSE_SUPPORT},
{"RTL8168E-VL/8111E-VL",
MCFG_8168E_VL_2,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k,
EFUSE_SUPPORT},
{"RTL8168F/8111F",
MCFG_8168F_1,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k,
EFUSE_SUPPORT},
{"RTL8168F/8111F",
MCFG_8168F_2,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k},
{"RTL81xx/20",
CFG_METHOD_20,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k},
{"RTL81xx/21",
CFG_METHOD_21,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k},
{"RTL81xx/22",
CFG_METHOD_22,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k},
{"RTL81xx/23",
CFG_METHOD_23,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k},
{"RTL81xx/24",
CFG_METHOD_24,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k},
//
// RTL8169/8110 Family
//
{"RTL8169",
MCFG_8169_1,
256,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_7k,
EFUSE_NOT_SUPPORT},
{"RTL8169S/8110S",
MCFG_8169S_1,
256,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_7k,
EFUSE_NOT_SUPPORT},
{"RTL8169S/8110S",
MCFG_8169S_2,
256,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_7k,
EFUSE_NOT_SUPPORT},
{"RTL8169SB/8110SB",
MCFG_8169SB_1,
256,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_7k,
EFUSE_NOT_SUPPORT},
{"RTL8169SC/8110SC",
MCFG_8169SC_1,
256,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_7k,
EFUSE_NOT_SUPPORT},
{"RTL8169SC/8110SC",
MCFG_8169SC_2,
256,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_7k,
EFUSE_NOT_SUPPORT},
//
// RTL8401
//
{"RTL8401",
MCFG_8401_1,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
{"RTL8401",
MCFG_8402_1,
1024,
(RX_FIFO_THRESH_NONE << RxCfgFIFOShift) | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
0,
EFUSE_NOT_SUPPORT},
//
// RTL8411
//
{"RTL8411",
MCFG_8411_1,
1024,
RxCfg_128_int_en | (RX_DMA_BURST << RxCfgDMAShift),
0xff7e1880,
Jumbo_Frame_9k,
EFUSE_NOT_SUPPORT},
// *** end of table ***
{ 0 }
};
//
// Power management table
//
struct IOPMPowerState RealtekR1000::powerStateArray[ kR1000PowerStateCount ] =
{
// kR1000PowerStateOff
{ kIOPMPowerStateVersion1,0,0,0,0,0,0,0,0,0,0,0 },
// kR1000PowerStateOn
{ kIOPMPowerStateVersion1, // version
IOPMDeviceUsable, // capability
IOPMPowerOn, // pwr character
IOPMPowerOn, // pwr requirement
// below this line unused, 0 is OK
0, // static pwr in mw
0, // unbudgeted pwr
0, // pwr to attain
0, // time to attain in us
0, // settle up time
0, // time to lower
0, // settle down time
0 // power domain budget
}
};
/* Maximum events (Rx packets, etc.) to handle at each interrupt. */
int RealtekR1000::max_interrupt_work = 20;
/* Maximum number of multicast addresses to filter (vs. Rx-all-multicast).
The RTL chips use a 64 element hash table based on the Ethernet CRC. */
UInt32 RealtekR1000::multicast_filter_limit = 32;
const u32 RealtekR1000::ethernet_polynomial = 0x04c11db7U;
// Default interrupt mask. See chip-specific code for more.
const u16 RealtekR1000::r1000_intr_mask =
LinkChg | RxDescUnavail | RxFIFOOver | TxErr | TxOK | RxErr | RxOK ;
/*
* Initialization of driver instance,
* i.e. resources allocation and so on.
*/
// FIXME - be sure to initialize all member variables!
bool RealtekR1000::init(OSDictionary *properties)
{
//
// logging
//
strncpy(bsdName, "RealtekR1000", BSD_NAME_LEN);
DLog("init\n");
if (BaseClass::init(properties) == false)
{
DLog("BaseClass::init() returned false!\n");
return false;
}
//
// pointers to OS objects
//
pciDev = NULL;
workLoop = NULL;
intSource = NULL;
timerSource = NULL;
netStats = NULL;
etherStats = NULL;
transmitQueue = NULL;
etherif = NULL;
mediumDict = NULL;
//
// capabilities to advertise to OS
//
canOffload = 0;
//
// internal driver status
//
board_inited = false;
buffers_inited = false;
enabled = false;
linked = false;
activationLevel = kActivationLevelNone;
enabledForKDP = enabledForBSD = false;
powerState = kR1000PowerStateOn; // presume power is already on at startup
//
// Tx & Rx ring buffer management
//
R1000InitRingIndices();
rxdesc_space = NULL;
RxDescArray = NULL;
rx_descMd = NULL;
rxdesc_phy_dma_addr = NULL;
txdesc_space = NULL;
TxDescArray = NULL;
tx_descMd = NULL;
txdesc_phy_dma_addr = NULL;
for (int i = 0; i < NUM_TX_DESC; i++)
{
Tx_skbuff[i] = NULL;
}
InitializeBufferMemoryPointers();
//
// register addressing
//
pioBase = 0;
mmioBase = NULL;
forcedPio = true;
return true;
}
/*
* Calling before destroying driver instance.
* Frees all allocated resources.
*/
void RealtekR1000::free()
{
DLog("free\n");
// give back our buffer pool
FreeBufferMemory();
FreeDescriptorsMemory();
//free resource of base instance
if (intSource && workLoop)
{
//Detaching interrupt source from work loop
workLoop->removeEventSource(intSource);
}
// TODO - figure out if this order is significant!
// TODO - release contents of various pointer tables
RELEASE(etherif);
RELEASE(intSource);
RELEASE(timerSource);
RELEASE(mmioBase);
RELEASE(pciDev);
RELEASE(workLoop);
RELEASE(mediumDict);
BaseClass::free();
}
/*
* Starting driver.
*/
bool RealtekR1000::start(IOService *provider)
{
DLog("start\n");
if (!BaseClass::start(provider))
{
DLog("start: Failed, super::start returned false\n");
return false;
}
pciDev = OSDynamicCast(IOPCIDevice, provider);
if (pciDev == NULL)
{
DLog("start: Failed, provider is not IOPCIDevice\n");
return false;
}
// Increment OS reference count
pciDev->retain();
if (!pciDev->open(this))
{
DLog("start: Failed to open PCI Device/Nub\n");
return false;
}
bool success = false;
do
{
// FIXME - Defer adding Gigabit media until we've ID'd the chip
// See Apple driver: RTL8139PHY.cpp
// Assuming RTL8168B/8111B by default
// Actual chipset will be ID'd in R1000InitBoard(),
// called from R1000ProbeAndStartBoard() below
mcfg = MCFG_8168B_1;
//Adding Mac OS X PHY's
mediumDict = OSDictionary::withCapacity(MEDIUM_INDEX_COUNT + 1);
OSAddNetworkMedium(kIOMediumEthernetAuto, 0, MEDIUM_INDEX_AUTO);
OSAddNetworkMedium(kIOMediumEthernet10BaseT | kIOMediumOptionHalfDuplex, 10 * MBit, MEDIUM_INDEX_10HD);
OSAddNetworkMedium(kIOMediumEthernet10BaseT | kIOMediumOptionFullDuplex, 10 * MBit, MEDIUM_INDEX_10FD);
OSAddNetworkMedium(kIOMediumEthernet100BaseTX | kIOMediumOptionHalfDuplex, 100 * MBit, MEDIUM_INDEX_100HD);
OSAddNetworkMedium(kIOMediumEthernet100BaseTX | kIOMediumOptionFullDuplex, 100 * MBit, MEDIUM_INDEX_100FD);
OSAddNetworkMedium(kIOMediumEthernet1000BaseTX | kIOMediumOptionHalfDuplex, 1000 * MBit, MEDIUM_INDEX_1000HD);
OSAddNetworkMedium(kIOMediumEthernet1000BaseTX | kIOMediumOptionFullDuplex, 1000 * MBit, MEDIUM_INDEX_1000FD);
if (!publishMediumDictionary(mediumDict))
{
DLog("start: Failed, publishMediumDictionary returned false\n");
break;
}
if (!R1000ProbeAndStartBoard())
{
DLog("start: Failed, R1000ProbeAndStartBoard returned false\n");
break;
}
if (!AllocateDescriptorsMemory())
{
DLog("start: Failed, AllocateDescriptorsMemory returned false\n");
break;
}
if (!AllocateBufferMemory())
{
DLog("start: Failed, AllocateBufferMemory returned false\n");
break;
}
InitializeRingBufferDescriptors();
if (!R1000InitEventSources(provider))
{
DLog("start: Failed, R1000InitEventSources returned false\n");
break;
}
// set up power management
PMinit();
pciDev->joinPMtree(this);
success = true;
}
while ( false );
// Close our provider, it will be re-opened on demand when
// our enable() is called by a client.
if (pciDev != NULL)
{
pciDev->close(this);
}
do
{
// break if we've had an error before this
if ( false == success )
{
break;
}
// Attaching dynamic link layer
// Callback to configureInterface() method happens here
if (false == attachInterface((IONetworkInterface**)ðerif, false))
{
DLog("start: Failed 'attachInterface' in attaching to data link layer\n");
break;
}
// Do this here instead of in attachInterface() to allow us to cleanly finish initializing
etherif->registerService();
success = true;
}
while ( false );
DLog("start: returning '%d'\n",success);
return success;
}
/*
* Stopping driver.
*/
// FIXME - should we return buffer memory here?
void RealtekR1000::stop(IOService *provider)
{
DLog("stop\n");
detachInterface(etherif);
R1000StopBoard();
PMstop();
BaseClass::stop(provider);
}
bool RealtekR1000::OSAddNetworkMedium(ulong type, UInt32 bps, ulong index)
{
IONetworkMedium *medium = IONetworkMedium::medium(type, bps, 0, index);
if (!medium)
{
IOLog("Couldn't allocate medium\n");
return false;
}
if (!IONetworkMedium::addMedium(mediumDict, medium))
{
IOLog("Couldn't add medium\n");
return false;
}
mediumTable[index] = medium;
return true;
}
bool RealtekR1000::increaseActivationLevel(UInt32 level)
{
bool ret = false;
switch (level)
{
case kActivationLevelKDP:
{
if (!pciDev) break;
pciDev->open(this);
// PHY medium selection.
const IONetworkMedium *medium = getSelectedMedium();
if (!medium) {
DLog("Selected medium is NULL, forcing to autonegotiation\n");
medium = mediumTable[MEDIUM_INDEX_AUTO];
} else {
DLog("Selected medium index %u\n",(unsigned int)medium->getIndex());
}
selectMedium(medium);
// FIXME - why is this here? Anything to do with link_timer in Linux?
//timerSource->setTimeoutMS(TX_TIMEOUT);
ret = true;
break;
}
case kActivationLevelBSD:
{
if (!R1000OpenAdapter()) break;
transmitQueue->setCapacity(kTransmitQueueCapacity);
transmitQueue->start();
ret = true;
break;
}
}
return ret;
}
bool RealtekR1000::decreaseActivationLevel(UInt32 level)
{
switch (level)
{
case kActivationLevelKDP:
// FIXME - why is this here? Anything to do with link_timer in Linux?
//timerSource->cancelTimeout();
if (pciDev) pciDev->close(this);
break;
case kActivationLevelBSD:
transmitQueue->stop();
transmitQueue->setCapacity(0);
transmitQueue->flush();
R1000CloseAdapter();
break;
}
return true;
}
bool RealtekR1000::setActivationLevel(UInt32 level)
{
DLog("setActivationLevel(%u)\n", (unsigned int)level);
if (activationLevel == level)
return true;
bool success = false;
for ( ; activationLevel > level; activationLevel--) {
if (!(success = decreaseActivationLevel(activationLevel)))
break;
}
for ( ; activationLevel < level; activationLevel++ ) {
if (!(success = increaseActivationLevel(activationLevel+1)))
break;
}
return success;
}
/*
* A request from an interface client to enable the controller.
*/
IOReturn RealtekR1000::enable(IONetworkInterface *netif)
{
DLog("enable\n");
if (enabledForBSD)
return kIOReturnSuccess;
enabledForBSD = setActivationLevel(kActivationLevelBSD);
if (enabledForBSD) {
enabled = true;
return kIOReturnSuccess;
} else
return kIOReturnIOError;
}
/*
* A request from an interface client to disable the controller.
*/
IOReturn RealtekR1000::disable(IONetworkInterface *netif)
{
DLog("disable\n");
enabledForBSD = false;
setActivationLevel(enabledForKDP ? kActivationLevelKDP : kActivationLevelNone);
enabled = false;
return kIOReturnSuccess;
}
bool RealtekR1000::setLinkStatus( UInt32 status,
const IONetworkMedium *activeMedium,
UInt64 speedSt,
OSData *data )
{
// DLog("setLinkStatus speed=%lld\n", speedSt);
return BaseClass::setLinkStatus( status, activeMedium, speedSt, data );
}/* end setLinkStatus */
/*
* Transmits an output packet.
* packet - an mbuf chain containing the output packet to be sent on the network.
* param - a parameter provided by the caller.
*/
// TODO - implement checksum offload
UInt32 RealtekR1000::outputPacket(mbuf_t m, void *param)
{
// DLog("outputPacket, length = %lu\n", mbuf_pkthdr_len(m));
#ifdef DEBUG
if (!buffers_inited)
{
DLog("outputPacket: buffers not initialized!!\n");
return kIOReturnOutputStall;
}
#endif
// Is packet larger than MTU?
if (mbuf_pkthdr_len(m) > tx_pkt_len)
{
DLog("Tx Packet size is too big, dropping\n");
freePacket(m);
return kIOReturnOutputDropped;
}
ulong buf_len = static_cast<ulong>(mbuf_pkthdr_len(m));
// Allocate an entry in the Tx buffer descriptor ring
ulong entry = OSIncrementAtomic(&cur_tx) % n_tx_desc;
// Is this entry available?
if ((OSSwapLittleToHostInt32(TxDescArray[entry].status) & DescOwn))
{
DLog("TX_RING_IS_FULL, stalling\n");
return kIOReturnOutputStall;
}
// copy user packet into Tx buffer, coalescing if needed
uchar *data_ptr = TxBufferVirtualAddress(entry);
ulong pkt_snd_len = 0;
mbuf_t cur_buf = m;
while ((cur_buf != NULL) && (pkt_snd_len <= buf_len))
{
// Sanity check chunk size
size_t cur_buf_len = mbuf_len(cur_buf);
if (cur_buf_len > (buf_len - pkt_snd_len))
{
DLog("Tx Packet mbuf chain malformed, dropping\n");
freePacket(m);
return kIOReturnOutputDropped;
}
if (mbuf_data(cur_buf))
{
bcopy(mbuf_data(cur_buf), data_ptr, cur_buf_len);
data_ptr += cur_buf_len;
pkt_snd_len += static_cast<ulong>(cur_buf_len);
}
cur_buf = mbuf_next(cur_buf);
}
// final sanity check
if (buf_len != pkt_snd_len)
{
DLog("Tx Packet mbuf chain missing data, dropping\n");
freePacket(m);
return kIOReturnOutputDropped;
}
// now can log the packet as in the queue
Tx_skbuff[entry] = m;
// mark the descriptor as ready to send
if (entry == (n_tx_desc - 1))
{
TxDescArray[entry].status = OSSwapHostToLittleInt32((DescOwn | RingEnd | FirstFrag | LastFrag) | pkt_snd_len);
}
else
{
TxDescArray[entry].status = OSSwapHostToLittleInt32((DescOwn | FirstFrag | LastFrag) | pkt_snd_len);
}
// tell the chip there's work to do
WriteMMIO8(TxPoll, 0x40); // Normal Priority Queue bit
return kIOReturnOutputSuccess;
}
void RealtekR1000::getPacketBufferConstraints(IOPacketBufferConstraints *constraints) const
{
//DLog("getPacketBufferConstraints\n");
constraints->alignStart = kIOPacketBufferAlign4;
constraints->alignLength = kIOPacketBufferAlign4;
}
IOOutputQueue *RealtekR1000::createOutputQueue()
{
//DLog("createOutputQueue\n");
// Slight optimization
// switch back if Tx/Rx conflicts cause problems
//return IOGatedOutputQueue::withTarget(this, getWorkLoop());
return IOBasicOutputQueue::withTarget(this);
}
/*
* Returns a string describing the vendor of the network controller. The caller is responsible for releasing the string object returned.
*/
const OSString *RealtekR1000::newVendorString() const
{
return OSString::withCString("Realtek");
}
/*
* Returns a string describing the model of the network controller. The caller is responsible for releasing the string object returned.
*/
const OSString *RealtekR1000::newModelString() const
{
return OSString::withCString(rtl_chip_info[mcfg].name);
}
/*
* A client request to change the medium selection.
* This method is called when a client issues a command for the controller to change its
* current medium selection. The implementation must call setSelectedMedium() after the change
* has occurred. This method call is synchronized by the workloop's gate.
*/
IOReturn RealtekR1000::selectMedium(const IONetworkMedium *medium)
{
if (!medium) {
medium = mediumTable[MEDIUM_INDEX_AUTO];
}
if (!medium)
{
// DLog("Selected medium is NULL\n");
return kIOReturnBadArgument;
}
DLog("selectMedium, index=%u\n", (unsigned int)medium->getIndex());
switch (medium->getIndex())
{
case MEDIUM_INDEX_AUTO:
R1000SetMedium(SPEED_100, DUPLEX_FULL, AUTONEG_ENABLE);
break;
case MEDIUM_INDEX_10HD:
R1000SetMedium(SPEED_10, DUPLEX_HALF, AUTONEG_DISABLE);
break;
case MEDIUM_INDEX_10FD:
R1000SetMedium(SPEED_10, DUPLEX_FULL, AUTONEG_DISABLE);
break;
case MEDIUM_INDEX_100HD:
R1000SetMedium(SPEED_100, DUPLEX_HALF, AUTONEG_DISABLE);
break;
case MEDIUM_INDEX_100FD:
R1000SetMedium(SPEED_100, DUPLEX_FULL, AUTONEG_DISABLE);
break;
case MEDIUM_INDEX_1000HD:
R1000SetMedium(SPEED_1000, DUPLEX_HALF, AUTONEG_DISABLE);
break;
case MEDIUM_INDEX_1000FD:
R1000SetMedium(SPEED_1000, DUPLEX_FULL, AUTONEG_DISABLE);
break;
}
this->setSelectedMedium(medium);
if (ReadMMIO8(PHYstatus) & LinkStatus)