/* GT64260eth.c : GT64260 10/100 Mb ethernet MAC driver
*
* Copyright (c) 2003,2004 Brookhaven National Laboratory
* S. Kate Feng <feng1@bnl.gov>
* All rights reserved
*
* Acknowledgements:
* netBSD : Copyright (c) 2002 Allegro Networks, Inc., Wasabi Systems, Inc.
* Marvell : NDA document for the discovery system controller
*
* Some notes from the author, S. Kate Feng :
*
* 1) Mvme5500 uses Eth0 (controller 0) of the GT64260 to implement
* the 10/100 BaseT Ethernet with PCI Master Data Byte Swap\
* control.
* 2) Implemented hardware snoop instead of software snoop
* to ensure SDRAM cache coherency. (Copyright : NDA item)
* 3) Added S/W support for multi mbuf. (TODO : Let the H/W do it)
*
*/
#define __INSIDE_RTEMS_BSD_TCPIP_STACK__
#define BYTE_ORDER BIG_ENDIAN
#include <rtems.h>
#include <rtems/bspIo.h> /* printk */
#include <rtems/error.h>
#include <rtems/rtems_bsdnet.h>
#include <rtems/rtems_bsdnet_internal.h>
#include <stdio.h> /* printf for statistics */
#include <string.h>
#include <libcpu/io.h> /* inp & friends */
#include <libcpu/spr.h> /* registers.h is included here */
#include <bsp.h>
#include <sys/param.h>
#include <sys/systm.h>
#include <sys/mbuf.h>
#include <errno.h>
/* #include <sys/queue.h> */
#include <sys/socket.h>
#include <sys/sockio.h> /* SIOCADDMULTI, SIOC... */
#include <net/if.h>
#include <net/if_dl.h>
#include <netinet/in.h>
#include <netinet/if_ether.h>
#ifdef INET
#include <netinet/in_var.h>
#endif
#include <bsp/irq.h>
#include <bsp/GT64260ethreg.h>
#include <bsp/GT64260eth.h>
#include <bsp/VPD.h>
extern unsigned char ReadConfVPD_buff(int offset); /* in startup/bspstart.c */
#define GT_ETH_TASK_NAME "Geth"
#define PKT_BUF_SZ 1536
#define SOFTC_ALIGN 31
#define HASH_ALIGN 15
#define TXQ_HiLmt_OFF 2
/* <skf>
* 1. printk debug is for diagnosis only, which may cause
* unexpected result, especially if txq is under heavy load
* because CPU is fast with a decent cache.
*/
#define GTeth_debug 0
#define GTeth_rx_debug 0
#if 0
#define GE_FORGOT
#define GE_NORX
#define GT_DEBUG
#endif
/* RTEMS event to kill the daemon */
#define KILL_EVENT RTEMS_EVENT_1
/* RTEMS event to (re)start the transmitter */
#define START_TRANSMIT_EVENT RTEMS_EVENT_2
/* RTEMS events used by the ISR */
#define RX_EVENT RTEMS_EVENT_3
#define TX_EVENT RTEMS_EVENT_4
#define ERR_EVENT RTEMS_EVENT_5
#define ALL_EVENTS (KILL_EVENT|START_TRANSMIT_EVENT|RX_EVENT|TX_EVENT|ERR_EVENT)
enum GTeth_whack_op {
GE_WHACK_START, GE_WHACK_RESTART,
GE_WHACK_CHANGE, GE_WHACK_STOP
};
enum GTeth_hash_op {
GE_HASH_ADD, GE_HASH_REMOVE,
};
#define ET_MINLEN 64 /* minimum message length */
static int GTeth_ifioctl(struct ifnet *ifp, ioctl_command_t cmd, caddr_t data);
static void GTeth_ifstart (struct ifnet *);
static void GTeth_ifchange(struct GTeth_softc *sc);
static void GTeth_init_rx_ring(struct GTeth_softc *sc);
static void GT64260eth_daemon(void *arg);
static int GT64260eth_sendpacket(struct GTeth_softc *sc,struct mbuf *m);
static unsigned GTeth_txq_done(struct GTeth_softc *sc);
static void GTeth_tx_cleanup(struct GTeth_softc *sc);
static void GTeth_tx_start(struct GTeth_softc *sc);
static void GTeth_tx_stop(struct GTeth_softc *sc);
static void GTeth_rx_cleanup(struct GTeth_softc *sc);
static int GT64260eth_rx(struct GTeth_softc *sc);
static void GTeth_rx_setup(struct GTeth_softc *sc);
static void GTeth_rxprio_setup(struct GTeth_softc *sc);
static void GTeth_rx_stop(struct GTeth_softc *dc);
static void GT64260eth_isr(void);
static int GTeth_hash_compute(struct GTeth_softc *sc,unsigned char eaddr[ETHER_ADDR_LEN]);
static int GTeth_hash_entry_op(struct GTeth_softc *sc, enum GTeth_hash_op op,
enum GTeth_rxprio prio,unsigned char eaddr[ETHER_ADDR_LEN]);
static int GTeth_hash_fill(struct GTeth_softc *sc);
static void GTeth_hash_init(struct GTeth_softc *sc);
static struct GTeth_softc *root_GT64260eth_dev = NULL;
static void GT64260eth_irq_on(const rtems_irq_connect_data *irq)
{
struct GTeth_softc *sc;
for (sc= root_GT64260eth_dev; sc; sc= sc-> next_module) {
outl(0x30883444,ETH0_EIMR); /* MOTLoad default interrupt mask */
return;
}
}
static void GT64260eth_irq_off(const rtems_irq_connect_data *irq)
{
struct GTeth_softc *sc;
for (sc= root_GT64260eth_dev; sc; sc= sc-> next_module)
outl(0, ETH0_EIMR);
}
static int GT64260eth_irq_is_on(const rtems_irq_connect_data *irq)
{
return(inl(ETH0_EICR) & ETH_IR_EtherIntSum);
}
static void GT64260eth_isr(void)
{
struct GTeth_softc *sc = root_GT64260eth_dev;
rtems_event_set events=0;
uint32_t cause;
cause = inl(ETH0_EICR);
outl( ~cause,ETH0_EICR); /* clear the ICR */
if ( (!cause) || (cause & 0x803d00)) {
sc->intr_errsts[sc->intr_err_ptr2++]=cause;
sc->intr_err_ptr2 %=INTR_ERR_SIZE; /* Till Straumann */
events |= ERR_EVENT;
}
/* ETH_IR_RxBuffer_3|ETH_IR_RxError_3 */
if (cause & 0x880000) {
sc->stats.rxInterrupts++;
events |= RX_EVENT;
}
/* If there is an error, we want to continue to next descriptor */
/* ETH_IR_TxBufferHigh|ETH_IR_TxEndHigh|ETH_IR_TxErrorHigh */
if (cause & 0x444) {
sc->stats.txInterrupts++;
events |= TX_EVENT;
/* It seems to be unnecessary. However, it's there
* to be on the safe side due to the datasheet.
* So far, it does not seem to affect the network performance
* based on the EPICS catime.
*/
/* ETH_ESDCMR_TXDH | ETH_ESDCMR_ERD = 0x800080 */
if ((sc->txq_nactive > 1)&& ((inl(ETH0_ESDCMR)Ð_ESDCMR_TXDH)==0))
outl(0x800080,ETH0_ESDCMR);
}
rtems_bsdnet_event_send(sc->daemonTid, events);
}
static rtems_irq_connect_data GT64260ethIrqData={
BSP_MAIN_ETH0_IRQ,
(rtems_irq_hdl) GT64260eth_isr,
NULL,
(rtems_irq_enable) GT64260eth_irq_on,
(rtems_irq_disable) GT64260eth_irq_off,
(rtems_irq_is_enabled) GT64260eth_irq_is_on,
};
static void GT64260eth_init_hw(struct GTeth_softc *sc)
{
#ifdef GT_DEBUG
printk("GT64260eth_init_hw(");
#endif
/* Kate Feng : Turn the hardware snoop on as MOTLoad did not have
* it on by default.
*/
outl(RxBSnoopEn|TxBSnoopEn|RxDSnoopEn|TxDSnoopEn, GT_CUU_Eth0_AddrCtrlLow);
outl(HashSnoopEn, GT_CUU_Eth0_AddrCtrlHigh);
sc->rxq_intrbits=0;
sc->sc_flags=0;
#ifndef GE_NORX
GTeth_rx_setup(sc);
#endif
#ifndef GE_NOTX
GTeth_tx_start(sc);
#endif
sc->sc_pcr |= ETH_EPCR_HS_512;
outl(sc->sc_pcr, ETH0_EPCR);
outl(sc->sc_pcxr, ETH0_EPCXR); /* port config. extended reg. */
outl(0, ETH0_EICR); /* interrupt cause register */
outl(sc->sc_intrmask, ETH0_EIMR);
#ifndef GE_NOHASH
/* Port Hash Table Pointer Reg*/
outl(((unsigned) sc->sc_hashtable),ETH0_EHTPR);
#endif
#ifndef GE_NORX
outl(ETH_ESDCMR_ERD,ETH0_ESDCMR); /* enable Rx DMA in SDMA Command Register */
sc->sc_flags |= GE_RXACTIVE;
#endif
#ifdef GT_DEBUG
printk("SDCMR 0x%x ", inl(ETH0_ESDCMR));
#endif
/* connect the interrupt handler which should
* take care of enabling interrupts
*/
if (!BSP_install_rtems_irq_handler(>64260ethIrqData))
printk("GT64260eth: unable to install ISR");
/* The ethernet port is ready to transmit/receive */
outl(sc->sc_pcr | ETH_EPCR_EN, ETH0_EPCR);
#ifdef GT_DEBUG
printk(")\n");
#endif
}
static void GT64260eth_stop_hw(struct GTeth_softc *sc)
{
printk("GT64260eth_stop_hw(");
/* remove our interrupt handler which will also
* disable interrupts at the MPIC and the device
* itself
*/
if (!BSP_remove_rtems_irq_handler(>64260ethIrqData))
printk("GT64260eth: unable to remove IRQ handler!");
outl(sc->sc_pcr, ETH0_EPCR);
outl(0, ETH0_EIMR);
sc->arpcom.ac_if.if_flags &= ~IFF_RUNNING;
#ifndef GE_NOTX
GTeth_tx_stop(sc);
#endif
#ifndef GE_NORX
GTeth_rx_stop(sc);
#endif
sc->sc_hashtable = NULL;
if (GTeth_debug>0) printk(")");
}
static void GT64260eth_stop(struct GTeth_softc *sc)
{
if (GTeth_debug>0) printk("GT64260eth_stop(");
/* The hardware is shutdown in the daemon */
/* kill the daemon. We also must release the networking
* semaphore or there'll be a deadlock...
*/
rtems_bsdnet_event_send(sc->daemonTid, KILL_EVENT);
rtems_bsdnet_semaphore_release();
sc->daemonTid=0;
/* now wait for it to die */
rtems_semaphore_obtain(sc->daemonSync,RTEMS_WAIT,RTEMS_NO_TIMEOUT);
/* reacquire the bsdnet semaphore */
rtems_bsdnet_semaphore_obtain();
if (GTeth_debug>0) printk(")");
}
static void GT64260eth_ifinit(void *arg)
{
struct GTeth_softc *sc = (struct GTeth_softc*)arg;
int i;
#ifdef GT_DEBUG
printk("GT64260eth_ifinit(): daemon ID: 0x%08x)\n", sc->daemonTid);
#endif
if (sc->daemonTid) {
#ifdef GT_DEBUG
printk("GT64260eth: daemon already up, doing nothing\n");
#endif
return;
}
#ifndef GE_NOHASH
/* Mvme5500, the user must initialize the hash table before enabling the
* Ethernet controller
*/
GTeth_hash_init(sc);
GTeth_hash_fill(sc);
#endif
sc->intr_err_ptr1=0;
sc->intr_err_ptr2=0;
for (i=0; i< INTR_ERR_SIZE; i++) sc->intr_errsts[i]=0;
/* initialize the hardware (we are holding the network semaphore at this point) */
(void)GT64260eth_init_hw(sc);
/* launch network daemon */
/* NOTE:
* in ss-20011025 (and later) any task created by 'bsdnet_newproc' is
* wrapped by code which acquires the network semaphore...
*/
sc->daemonTid = rtems_bsdnet_newproc(GT_ETH_TASK_NAME,4096,GT64260eth_daemon,arg);
/* Tell the world that we're running */
sc->arpcom.ac_if.if_flags |= IFF_RUNNING;
}
/* attach parameter tells us whether to attach or to detach the driver */
/* Attach this instance, and then all the sub-devices */
int rtems_GT64260eth_driver_attach(struct rtems_bsdnet_ifconfig *config, int attach)
{
struct GTeth_softc *sc;
struct ifnet *ifp;
unsigned sdcr, data;
unsigned char hwaddr[6];
int i, unit, phyaddr;
void *softc_mem;
char *name;
unit = rtems_bsdnet_parse_driver_name(config, &name);
if (unit < 0) return 0;
printk("\nEthernet driver name %s unit %d \n",name, unit);
printk("RTEMS-mvme5500 BSP Copyright (c) 2004, Brookhaven National Lab., Shuchen Kate Feng \n");
/* Make certain elements e.g. descriptor lists are aligned. */
softc_mem = rtems_bsdnet_malloc(sizeof(*sc) + SOFTC_ALIGN, M_FREE, M_NOWAIT);
/* Check for the very unlikely case of no memory. */
if (softc_mem == NULL)
printk("GT64260eth: OUT OF MEMORY");
sc = (void *)(((long)softc_mem + SOFTC_ALIGN) & ~SOFTC_ALIGN);
memset(sc, 0, sizeof(*sc));
if (GTeth_debug>0) printk("txq_desc[0] addr:%x, rxq_desc[0] addr:%x, sizeof sc %d\n",&sc->txq_desc[0], &sc->rxq_desc[0], sizeof(*sc));
sc->sc_macno = unit-1;
data = inl(ETH_EPAR);
phyaddr = ETH_EPAR_PhyAD_GET(data, sc->sc_macno);
/* try to read HW address from the device if not overridden
* by config
*/
if (config->hardware_address) {
memcpy(hwaddr, config->hardware_address, ETHER_ADDR_LEN);
} else {
printk("Read EEPROM ");
for (i = 0; i < 6; i++)
hwaddr[i] = ReadConfVPD_buff(VPD_ENET0_OFFSET+i);
}
#ifdef GT_DEBUG
printk("using MAC addr from device:");
for (i = 0; i < ETHER_ADDR_LEN; i++) printk("%x:", hwaddr[i]);
printk("\n");
#endif
memcpy(sc->arpcom.ac_enaddr, hwaddr, ETHER_ADDR_LEN);
ifp = &sc->arpcom.ac_if;
sc->sc_pcr = inl(ETH0_EPCR);
sc->sc_pcxr = inl(ETH0_EPCXR);
sc->sc_intrmask = inl(ETH0_EIMR) | ETH_IR_MIIPhySTC;
printk("address %s\n", ether_sprintf(hwaddr));
#ifdef GT_DEBUG
printk(", pcr %x, pcxr %x ", sc->sc_pcr, sc->sc_pcxr);
#endif
sc->sc_pcxr |= ETH_EPCXR_PRIOrx_Override;
sc->sc_pcxr |= (3<<6); /* highest priority only */
sc->sc_pcxr &= ~ETH_EPCXR_RMIIEn; /* MII mode */
/* Max. Frame Length (packet) allowed for reception is 1536 bytes,
* instead of 2048 (MOTLoad default) or 64K.
*/
sc->sc_pcxr &= ~(3 << 14);
sc->sc_pcxr |= (ETH_EPCXR_MFL_1536 << 14);
sc->sc_max_frame_length = PKT_BUF_SZ;
if (sc->sc_pcr & ETH_EPCR_EN) {
int tries = 1000;
/* Abort transmitter and receiver and wait for them to quiese*/
outl(ETH_ESDCMR_AR|ETH_ESDCMR_AT,ETH0_ESDCMR);
do {
rtems_bsp_delay(100);
} while (tries-- > 0 && (inl(ETH0_ESDCMR) & (ETH_ESDCMR_AR|ETH_ESDCMR_AT)));
}
#ifdef GT_DEBUG
printk(", phy %d (mii)\n", phyaddr);
printk("ETH0_ESDCMR %x ", inl(ETH0_ESDCMR));
#endif
sc->sc_pcr &= ~(ETH_EPCR_EN | ETH_EPCR_RBM | ETH_EPCR_PM | ETH_EPCR_PBF);
#ifdef GT_DEBUG
printk("Now sc_pcr %x,sc_pcxr %x", sc->sc_pcr, sc->sc_pcxr);
#endif
/*
* Now turn off the GT. If it didn't quiese, too ***ing bad.
*/
outl(sc->sc_pcr, ETH0_EPCR);
outl(sc->sc_intrmask, ETH0_EIMR);
sdcr = inl(ETH0_ESDCR);
/* Burst size is limited to 4 64bit words */
ETH_ESDCR_BSZ_SET(sdcr, ETH_ESDCR_BSZ_4);
sdcr |= ETH_ESDCR_RIFB;/*limit interrupt on frame boundaries, instead of buffer*/
#if 0
sdcr &= ~(ETH_ESDCR_BLMT|ETH_ESDCR_BLMR); /* MOTLoad defualt Big-endian */
#endif
outl(sdcr, ETH0_ESDCR);
#ifdef GT_DEBUG
printk("sdcr %x \n", sdcr);
#endif
if (phyaddr== -1) printk("MII auto negotiation ?");
ifp->if_flags = IFF_BROADCAST | IFF_SIMPLEX | IFF_MULTICAST;
ifp->if_softc = sc;
/* set this interface's name and unit */
ifp->if_unit = unit;
ifp->if_name = name;
ifp->if_mtu = config->mtu ? config->mtu : ETHERMTU;
ifp->if_init = GT64260eth_ifinit;
ifp->if_ioctl = GTeth_ifioctl;
ifp->if_start = GTeth_ifstart;
ifp->if_output = ether_output;
/* ifp->if_watchdog = GTeth_ifwatchdog;*/
if (ifp->if_snd.ifq_maxlen == 0)
ifp->if_snd.ifq_maxlen = ifqmaxlen;
/* create the synchronization semaphore */
if (RTEMS_SUCCESSFUL != rtems_semaphore_create(
rtems_build_name('G','e','t','h'),0,0,0,&sc->daemonSync))
printk("GT64260eth: semaphore creation failed");
sc->next_module = root_GT64260eth_dev;
root_GT64260eth_dev = sc;
/* Actually attach the interface */
if_attach(ifp);
ether_ifattach(ifp);
#ifdef GT_DEBUG
printk("GT64260eth: Ethernet driver has been attached (handle 0x%08x,ifp 0x%08x)\n",sc, ifp);
#endif
return(1);
}
static void GT64260eth_stats(struct GTeth_softc *sc)
{
#if 0
struct ifnet *ifp = &sc->arpcom.ac_if;
printf(" Rx Interrupts:%-8lu\n", sc->stats.rxInterrupts);
printf(" Receive Packets:%-8lu\n", ifp->if_ipackets);
printf(" Receive errors:%-8lu\n", ifp->if_ierrors);
printf(" Framing Errors:%-8lu\n", sc->stats.frame_errors);
printf(" Crc Errors:%-8lu\n", sc->stats.crc_errors);
printf(" Oversized Frames:%-8lu\n", sc->stats.length_errors);
printf(" Active Rxqs:%-8u\n", sc->rxq_active);
printf(" Tx Interrupts:%-8lu\n", sc->stats.txInterrupts);
#endif
printf("Multi-BuffTx Packets:%-8lu\n", sc->stats.txMultiBuffPacket);
printf("Multi-BuffTx max len:%-8lu\n", sc->stats.txMultiMaxLen);
printf("SingleBuffTx max len:%-8lu\n", sc->stats.txSinglMaxLen);
printf("Multi-BuffTx maxloop:%-8lu\n", sc->stats.txMultiMaxLoop);
printf("Tx buffer max len :%-8lu\n", sc->stats.txBuffMaxLen);
#if 0
printf(" Transmitt Packets:%-8lu\n", ifp->if_opackets);
printf(" Transmitt errors:%-8lu\n", ifp->if_oerrors);
printf(" Tx/Rx collisions:%-8lu\n", ifp->if_collisions);
printf(" Active Txqs:%-8u\n", sc->txq_nactive);
#endif
}
void GT64260eth_printStats(void)
{
GT64260eth_stats(root_GT64260eth_dev);
}
static int GTeth_ifioctl(struct ifnet *ifp, ioctl_command_t cmd, caddr_t data)
{
struct GTeth_softc *sc = ifp->if_softc;
struct ifreq *ifr = (struct ifreq *) data;
int error = 0;
#ifdef GT_DEBUG
printk("GTeth_ifioctl(");
#endif
switch (cmd) {
default:
if (GTeth_debug >0) {
printk("etherioctl(");
if (cmd== SIOCSIFADDR) printk("SIOCSIFADDR ");
}
return ether_ioctl(ifp, cmd, data);
case SIOCSIFFLAGS:
switch (ifp->if_flags & (IFF_UP|IFF_RUNNING)) {
case IFF_RUNNING: /* not up, so we stop */
GT64260eth_stop(sc);
break;
case IFF_UP: /* not running, so we start */
GT64260eth_ifinit(sc);
break;
case IFF_UP|IFF_RUNNING:/* active->active, update */
GT64260eth_stop(sc);
GT64260eth_ifinit(sc);
break;
default: /* idle->idle: do nothing */
break;
}
break;
case SIO_RTEMS_SHOW_STATS:
GT64260eth_stats (sc);
break;
case SIOCADDMULTI:
case SIOCDELMULTI:
error = (cmd == SIOCADDMULTI)
? ether_addmulti(ifr, &sc->arpcom)
: ether_delmulti(ifr, &sc->arpcom);
if (error == ENETRESET) {
if (ifp->if_flags & IFF_RUNNING)
GTeth_ifchange(sc);
else
error = 0;
}
break;
case SIOCSIFMTU:
if (ifr->ifr_mtu > ETHERMTU || ifr->ifr_mtu < ETHERMIN) {
error = EINVAL;
break;
}
ifp->if_mtu = ifr->ifr_mtu;
break;
}
#ifdef GT_DEBUG
printk("exit ioctl\n");
#endif
return error;
}
static void GTeth_ifstart(struct ifnet *ifp)
{
struct GTeth_softc *sc = ifp->if_softc;
#ifdef GT_DEBUG
printk("GTeth_ifstart(");
#endif
if ((ifp->if_flags & IFF_RUNNING) == 0) {
#ifdef GT_DEBUG
printk("IFF_RUNNING==0\n");
#endif
return;
}
ifp->if_flags |= IFF_OACTIVE;
rtems_bsdnet_event_send (sc->daemonTid, START_TRANSMIT_EVENT);
#ifdef GT_DEBUG
printk(")\n");
#endif
}
/* Initialize the Rx rings */
static void GTeth_init_rx_ring(struct GTeth_softc *sc)
{
int i;
volatile struct GTeth_desc *rxd;
unsigned nxtaddr;
sc->rxq_fi=0;
sc->rxq_head_desc = &sc->rxq_desc[0];
rxd = sc->rxq_head_desc;
sc->rxq_desc_busaddr = (unsigned long) sc->rxq_head_desc;
#ifdef GT_DEBUG
printk("rxq_desc_busaddr %x ,&sc->rxq_desc[0] %x\n",
sc->rxq_desc_busaddr, sc->rxq_head_desc);
#endif
nxtaddr = sc->rxq_desc_busaddr + sizeof(*rxd);
sc->rx_buf_sz = (sc->arpcom.ac_if.if_mtu <= 1500 ? PKT_BUF_SZ : sc->arpcom.ac_if.if_mtu + 32);
sc->rxq_active = RX_RING_SIZE;
for (i = 0; i < RX_RING_SIZE; i++, rxd++, nxtaddr += sizeof(*rxd)) {
struct mbuf *m;
rxd->ed_lencnt= sc->rx_buf_sz <<16;
rxd->ed_cmdsts = RX_CMD_F|RX_CMD_L|RX_CMD_O|RX_CMD_EI;
MGETHDR(m, M_WAIT, MT_DATA);
MCLGET(m, M_WAIT);
m->m_pkthdr.rcvif = &sc->arpcom.ac_if;
sc->rxq_mbuf[i] = m;
/* convert mbuf pointer to data pointer of correct type */
rxd->ed_bufptr = (unsigned) mtod(m, void *);
/*
* update the nxtptr to point to the next txd.
*/
if (i == RX_RING_SIZE - 1)
nxtaddr = sc->rxq_desc_busaddr;
rxd->ed_nxtptr = nxtaddr;
#ifdef GT_DEBUG
printk("ed_lencnt %x, rx_buf_sz %x ",rxd->ed_lencnt, sc->rx_buf_sz);
printk("ed_cmdsts %x \n",rxd->ed_cmdsts);
printk("mbuf @ 0x%x, next desc. @ 0x%x\n",rxd->ed_bufptr,rxd->ed_nxtptr);
#endif
}
}
void GTeth_rxprio_setup(struct GTeth_softc *sc)
{
GTeth_init_rx_ring(sc);
sc->rxq_intrbits = ETH_IR_RxBuffer|ETH_IR_RxError|ETH_IR_RxBuffer_3|ETH_IR_RxError_3;
}
static int GT64260eth_rx(struct GTeth_softc *sc)
{
struct ifnet *ifp = &sc->arpcom.ac_if;
struct mbuf *m;
int nloops=0;
#ifdef GT_DEBUG
if (GTeth_rx_debug>0) printk("GT64260eth_rx(");
#endif
while (sc->rxq_active > 0) {
volatile struct GTeth_desc *rxd = &sc->rxq_desc[sc->rxq_fi];
struct ether_header *eh;
unsigned int cmdsts;
unsigned int byteCount;
cmdsts = rxd->ed_cmdsts;
/*
* Sometimes the GE "forgets" to reset the ownership bit.
* But if the length has been rewritten, the packet is ours
* so pretend the O bit is set.
*
*/
byteCount = rxd->ed_lencnt & 0xffff;
if (cmdsts & RX_CMD_O) {
if (byteCount == 0)
return(0);
/* <Kate Feng> Setting command/status to be zero seems to eliminate
* the spurious interrupt associated with the GE_FORGOT issue.
*/
rxd->ed_cmdsts=0;
#ifdef GE_FORGOT
/*
* For dignosis purpose only. Not a good practice to turn it on
*/
printk("Rxq %d %d %d\n", sc->rxq_fi, byteCount,nloops);
#endif
}
/* GT gave the ownership back to the CPU or the length has
* been rewritten , which means there
* is new packet in the descriptor/buffer
*/
nloops++;
/*
* If this is not a single buffer packet with no errors
* or for some reason it's bigger than our frame size,
* ignore it and go to the next packet.
*/
if ((cmdsts & (RX_CMD_F|RX_CMD_L|RX_STS_ES)) !=
(RX_CMD_F|RX_CMD_L) ||
byteCount > sc->sc_max_frame_length) {
--sc->rxq_active;
ifp->if_ipackets++;
ifp->if_ierrors++;
if (cmdsts & RX_STS_OR) sc->stats.or_errors++;
if (cmdsts & RX_STS_CE) sc->stats.crc_errors++;
if (cmdsts & RX_STS_MFL) sc->stats.length_errors++;
if (cmdsts & RX_STS_SF) sc->stats.frame_errors++;
if ((cmdsts & RX_STS_LC) || (cmdsts & RX_STS_COL))
ifp->if_collisions++;
/* recycle the buffer */
m->m_len=sc->rx_buf_sz;
}
else {
m = sc->rxq_mbuf[sc->rxq_fi];
m->m_len = m->m_pkthdr.len = byteCount - sizeof(struct ether_header);
eh = mtod (m, struct ether_header *);
m->m_data += sizeof(struct ether_header);
ether_input (ifp, eh, m);
ifp->if_ipackets++;
ifp->if_ibytes+=byteCount;
--sc->rxq_active;
MGETHDR (m, M_WAIT, MT_DATA);
MCLGET (m, M_WAIT);
}
m->m_pkthdr.rcvif = ifp;
sc->rxq_mbuf[sc->rxq_fi]= m;
/* convert mbuf pointer to data pointer of correct type */
rxd->ed_bufptr = (unsigned) mtod(m, void*);
rxd->ed_lencnt = (unsigned long) sc->rx_buf_sz <<16;
rxd->ed_cmdsts = RX_CMD_F|RX_CMD_L|RX_CMD_O|RX_CMD_EI;
if (++sc->rxq_fi == RX_RING_SIZE) sc->rxq_fi = 0;
sc->rxq_active++;
} /* while (sc->rxq_active > 0) */
#ifdef GT_DEBUG
if (GTeth_rx_debug>0) printk(")");
#endif
return nloops;
}
static void GTeth_rx_setup(struct GTeth_softc *sc)
{
if (GTeth_rx_debug>0) printk("GTeth_rx_setup(");
GTeth_rxprio_setup(sc);
if ((sc->sc_flags & GE_RXACTIVE) == 0) {
/* First Rx Descriptor Pointer 3 */
outl( sc->rxq_desc_busaddr, ETH0_EFRDP3);
/* Current Rx Descriptor Pointer 3 */
outl( sc->rxq_desc_busaddr,ETH0_ECRDP3);
#ifdef GT_DEBUG
printk("ETH0_EFRDP3 0x%x, ETH0_ECRDP3 0x%x \n", inl(ETH0_EFRDP3),
inl(ETH0_ECRDP3));
#endif
}
sc->sc_intrmask |= sc->rxq_intrbits;
if (GTeth_rx_debug>0) printk(")\n");
}
static void GTeth_rx_cleanup(struct GTeth_softc *sc)
{
int i;
if (GTeth_rx_debug>0) printk( "GTeth_rx_cleanup(");
for (i=0; i< RX_RING_SIZE; i++) {
if (sc->rxq_mbuf[i]) {
m_freem(sc->rxq_mbuf[i]);
sc->rxq_mbuf[i]=0;
}
}
if (GTeth_rx_debug>0) printk(")");
}
static void GTeth_rx_stop(struct GTeth_softc *sc)
{
if (GTeth_rx_debug>0) printk( "GTeth_rx_stop(");
sc->sc_flags &= ~GE_RXACTIVE;
sc->sc_idlemask &= ~(ETH_IR_RxBits|ETH_IR_RxBuffer_3|ETH_IR_RxError_3);
sc->sc_intrmask &= ~(ETH_IR_RxBits|ETH_IR_RxBuffer_3|ETH_IR_RxError_3);
outl(sc->sc_intrmask, ETH0_EIMR);
outl(ETH_ESDCMR_AR, ETH0_ESDCMR); /* abort receive */
do {
rtems_bsp_delay(10);
} while (inl(ETH0_ESDCMR) & ETH_ESDCMR_AR);
GTeth_rx_cleanup(sc);
if (GTeth_rx_debug>0) printk(")");
}
static void GTeth_txq_free(struct GTeth_softc *sc, unsigned cmdsts)
{
struct ifnet *ifp = &sc->arpcom.ac_if;
volatile struct GTeth_desc *txd = &sc->txq_desc[sc->txq_fi];
/* ownership is sent back to CPU */
if (GTeth_debug>0) printk("txq%d,active %d\n", sc->txq_fi, sc->txq_nactive);
txd->ed_cmdsts &= ~TX_CMD_O; /* <skf> in case GT forgot */
/* statistics */
ifp->if_opackets++;
ifp->if_obytes += sc->txq_mbuf[sc->txq_fi]->m_len;
if (cmdsts & TX_STS_ES) {
ifp->if_oerrors++;
if ((cmdsts & TX_STS_LC) || (cmdsts & TX_STS_COL))
ifp->if_collisions++;
}
/* Free the original mbuf chain */
m_freem(sc->txq_mbuf[sc->txq_fi]);
sc->txq_mbuf[sc->txq_fi] = 0;
ifp->if_timer = 5;
sc->txq_free++;
if (++sc->txq_fi == TX_RING_SIZE) sc->txq_fi = 0;
--sc->txq_nactive;
}
#if UNUSED
static int txq_high_limit(struct GTeth_softc *sc)
{
/*
* Have we [over]consumed our limit of descriptors?
* Do we have enough free descriptors?
*/
if ( TX_RING_SIZE == sc->txq_nactive + TXQ_HiLmt_OFF) {
volatile struct GTeth_desc *txd2 = &sc->txq_desc[sc->txq_fi];
unsigned cmdsts;
cmdsts = txd2->ed_cmdsts;
if (cmdsts & TX_CMD_O) { /* Ownership (1=GT 0=CPU) */
int nextin;
/*
* Sometime the Discovery forgets to update the
* last descriptor. See if CPU owned the descriptor
* after it (since we know we've turned that to
* the discovery and if CPU owned it, the Discovery
* gave it back). If CPU does, we know the Discovery
* gave back this one but forgot to mark it back to CPU.
*/
nextin = (sc->txq_fi + 1) % TX_RING_SIZE;
if (sc->txq_desc[nextin].ed_cmdsts & TX_CMD_O) {
#if 0
printk("Overconsuming Tx descriptors!\n");
#endif
return 1;
}
printk("Txq %d forgot\n", sc->txq_fi);
}
/* Txq ring is almost full, let's free the current buffer here */
#if 0
printk("Txq ring near full, free desc%d\n",sc->txq_fi);
#endif
GTeth_txq_free(sc, cmdsts);
} /* end if ( TX_RING_SIZE == sc->txq_nactive + TXQ_HiLmt_OFF) */
return 0;
}
#endif
static int GT64260eth_sendpacket(struct GTeth_softc *sc,struct mbuf *m)
{
volatile struct GTeth_desc *txd = &sc->txq_desc[sc->txq_lo];
unsigned intrmask = sc->sc_intrmask;
unsigned loop=0, index= sc->txq_lo;
/*
* The end-of-list descriptor we put on last time is the starting point
* for this packet. The GT is supposed to terminate list processing on
* a NULL nxtptr but that currently is broken so a CPU-owned descriptor
* must terminate the list.
*/
intrmask = sc->sc_intrmask;
if ( !(m->m_next)) {/* single buffer packet */
sc->txq_mbuf[index]= m;
sc->stats.txSinglMaxLen= MAX(m->m_len, sc->stats.txSinglMaxLen);
}
else /* multiple mbufs in this packet */
{
struct mbuf *mtp, *mdest;
volatile unsigned char *pt;
int len, y;
#ifdef GT_DEBUG
printk("multi mbufs ");
#endif
MGETHDR(mdest, M_WAIT, MT_DATA);
MCLGET(mdest, M_WAIT);
pt = (volatile unsigned char *)mdest->m_data;
for (mtp=m,len=0;mtp;mtp=mtp->m_next) {
loop++;
if ( (y=(len+mtp->m_len)) > sizeof(union mcluster)) {
/* GT64260 allows us to chain the remaining to the next
* free descriptors.
*/
printk("packet size %x > mcluster %x\n", y,sizeof(union mcluster));
printk("GT64260eth : packet too large ");
}
memcpy((void *)pt,(char *)mtp->m_data, mtp->m_len);
pt += mtp->m_len;
#if 0
printk("%d ",mtp->m_len);
#endif
len += mtp->m_len;
sc->stats.txBuffMaxLen=MAX(mtp->m_len,sc->stats.txBuffMaxLen);
}
sc->stats.txMultiMaxLoop=MAX(loop, sc->stats.txMultiMaxLoop);
#if 0
printk("\n");
#endif
mdest->m_len=len;
/* free old mbuf chain */
m_freem(m);
sc->txq_mbuf[index] = m = mdest;
sc->stats.txMultiBuffPacket++;
sc->stats.txMultiMaxLen= MAX(m->m_len, sc->stats.txMultiMaxLen);
}
if (m->m_len < ET_MINLEN) m->m_len = ET_MINLEN;
txd->ed_bufptr = (unsigned) mtod(m, void*);
txd->ed_lencnt = m->m_len << 16;
/*txd->ed_cmdsts = TX_CMD_L|TX_CMD_GC|TX_CMD_P|TX_CMD_O|TX_CMD_F|TX_CMD_EI;*/
txd->ed_cmdsts = 0x80c70000;
while (txd->ed_cmdsts != 0x80c70000);
memBar();
#ifdef GT_DEBUG
printk("len = %d, cmdsts 0x%x ", m->m_len,txd->ed_cmdsts);
#endif
/*
* Tell the SDMA engine to "Fetch!"
* Start Tx high.
*/
sc->txq_nactive++;
outl(0x800080, ETH0_ESDCMR); /* ETH_ESDCMR_TXDH| ETH_ESDCMR_ERD */
if ( ++sc->txq_lo == TX_RING_SIZE) sc->txq_lo = 0;
sc->txq_free--;
#if 0
/*
* Since we have put an item into the packet queue, we now want
* an interrupt when the transmit queue finishes processing the
* list. But only update the mask if needs changing.
*/
intrmask |= sc->txq_intrbits & ( ETH_IR_TxEndHigh|ETH_IR_TxBufferHigh);
if (sc->sc_intrmask != intrmask) {
sc->sc_intrmask = intrmask;
outl(sc->sc_intrmask, ETH0_EIMR);
}
#endif
#if 0
printk("EICR= %x, EIMR= %x ", inl(ETH0_EICR), inl(ETH0_EIMR));
printk("%s:transmit frame #%d queued in slot %d.\n",
sc->arpcom.ac_if.if_name, sc->txq_lo, index);
printk("pcr %x, pcxr %x DMA dcr %x cmr %x\n", inl(ETH0_EPCR), inl(ETH0_EPCXR), inl(ETH0_ESDCR), inl(ETH0_ESDCMR));
#endif
return 1;
}
static unsigned GTeth_txq_done(struct GTeth_softc *sc)
{
if (GTeth_debug>0) printk("Txdone(" );
while (sc->txq_nactive > 0) {
/* next to be returned to the CPU */
volatile struct GTeth_desc *txd = &sc->txq_desc[sc->txq_fi];
unsigned cmdsts;
/* if GT64260 still owns it ....... */
if ((cmdsts = txd->ed_cmdsts) & TX_CMD_O) {
int nextin;
/* Someone quoted :
* "Sometimes the Discovery forgets to update the
* ownership bit in the descriptor."
* <skf> More correctly, the last descriptor of each
* transmitted frame is returned to CPU ownership and
* status is updated only after the actual transmission
* of the packet is completed. Also, if there is an error
* during transmission, we want to continue the
* transmission of the next descriptor, in additions to
* reporting the error.
*/
/* The last descriptor */
if (sc->txq_nactive == 1) return(0);
/*
* Sometimes the Discovery forgets to update the
* ownership bit in the descriptor. See if CPU owned
* the descriptor after it (since we know we've turned
* that to the Discovery and if CPU owned it now then the
* Discovery gave it back). If we do, we know the
* Discovery gave back this one but forgot to mark it
* back to CPU.
*/
nextin = (sc->txq_fi + 1) % TX_RING_SIZE;
if (sc->txq_desc[nextin].ed_cmdsts & TX_CMD_O) return(0);
printk("Txq%d forgot\n",sc->txq_fi);
} /* end checking GT64260eth owner */
GTeth_txq_free(sc, cmdsts);
} /* end while */
if (GTeth_debug>0) printk(")\n");
return(1);
}
static void GTeth_tx_start(struct GTeth_softc *sc)
{
int i;
volatile struct GTeth_desc *txd;
unsigned nxtaddr;
#ifdef GT_DEBUG
printk("GTeth_tx_start(");
#endif
sc->sc_intrmask &= ~(ETH_IR_TxEndHigh|ETH_IR_TxBufferHigh|
ETH_IR_TxEndLow |ETH_IR_TxBufferLow);
txd = &sc->txq_desc[0];
sc->txq_desc_busaddr = (unsigned long) &sc->txq_desc[0];
#ifdef GT_DEBUG
printk("txq_desc_busaddr %x, &sc->txq_desc[0] %x \n",
sc->txq_desc_busaddr,&sc->txq_desc[0]);
#endif
nxtaddr = sc->txq_desc_busaddr + sizeof(*txd);
sc->txq_pendq.ifq_maxlen = 10;
sc->txq_pendq.ifq_head= NULL;
sc->txq_pendq.ifq_tail= NULL;
sc->txq_nactive = 0;
sc->txq_fi = 0;
sc->txq_lo = 0;
sc->txq_inptr = PKT_BUF_SZ;
sc->txq_outptr = 0;
sc->txq_free = TX_RING_SIZE;
for (i = 0; i < TX_RING_SIZE;
i++, txd++, nxtaddr += sizeof(*txd)) {
sc->txq_mbuf[i]=0;
txd->ed_bufptr = 0;
/*
* update the nxtptr to point to the next txd.
*/
txd->ed_cmdsts = 0;
if ( i== TX_RING_SIZE-1) nxtaddr = sc->txq_desc_busaddr;
txd->ed_nxtptr = nxtaddr;
#ifdef GT_DEBUG
printk("next desc. @ 0x%x\n",txd->ed_nxtptr);
#endif
}
sc->txq_intrbits = ETH_IR_TxEndHigh|ETH_IR_TxBufferHigh;
sc->txq_esdcmrbits = ETH_ESDCMR_TXDH; /* Start Tx high */
sc->txq_epsrbits = ETH_EPSR_TxHigh;
/* offset to current tx desc ptr reg */
sc->txq_ectdp = (caddr_t)ETH0_ECTDP1;
/* Current Tx Desc Pointer 1 */
outl(sc->txq_desc_busaddr,ETH0_ECTDP1);
#ifdef GT_DEBUG
printk(")\n");
#endif
}
static void GTeth_tx_cleanup(struct GTeth_softc *sc)
{
int i;
for (i=0; i< TX_RING_SIZE; i++) {
if (sc->txq_mbuf[i]) {
m_freem(sc->txq_mbuf[i]);
sc->txq_mbuf[i]=0;
}
}
}
static void GTeth_tx_stop(struct GTeth_softc *sc)
{
/* SDMA command register : stop Tx high and low */
outl(ETH_ESDCMR_STDH|ETH_ESDCMR_STDL, ETH0_ESDCMR);
GTeth_txq_done(sc);
sc->sc_intrmask &= ~(ETH_IR_TxEndHigh|ETH_IR_TxBufferHigh|
ETH_IR_TxEndLow |ETH_IR_TxBufferLow);
GTeth_tx_cleanup(sc);
sc->arpcom.ac_if.if_timer = 0;
}
static void GTeth_ifchange(struct GTeth_softc *sc)
{
if (GTeth_debug>0) printk("GTeth_ifchange(");
if (GTeth_debug>5) printk("(pcr=%#x,imr=%#x)",inl(ETH0_EPCR),inl(ETH0_EIMR));
/* printk("SIOCADDMULTI (SIOCDELMULTI): is it about rx or tx ?\n");*/
outl(sc->sc_pcr | ETH_EPCR_EN, ETH0_EPCR);
outl(sc->sc_intrmask, ETH0_EIMR);
GTeth_ifstart(&sc->arpcom.ac_if);
/* Current Tx Desc Pointer 0 and 1 */
if (GTeth_debug>5) printk("(ectdp0=%#x, ectdp1=%#x)",
inl(ETH0_ECTDP0), inl(ETH0_ECTDP1));
if (GTeth_debug>0) printk(")");
}
static int GTeth_hash_compute(struct GTeth_softc *sc,unsigned char eaddr[ETHER_ADDR_LEN])
{
unsigned w0, add0, add1;
unsigned result;
if (GTeth_debug>0) printk("GTeth_hash_compute(");
add0 = ((unsigned) eaddr[5] << 0) |
((unsigned) eaddr[4] << 8) |
((unsigned) eaddr[3] << 16);
add0 = ((add0 & 0x00f0f0f0) >> 4) | ((add0 & 0x000f0f0f) << 4);
add0 = ((add0 & 0x00cccccc) >> 2) | ((add0 & 0x00333333) << 2);
add0 = ((add0 & 0x00aaaaaa) >> 1) | ((add0 & 0x00555555) << 1);
add1 = ((unsigned) eaddr[2] << 0) |
((unsigned) eaddr[1] << 8) |
((unsigned) eaddr[0] << 16);
add1 = ((add1 & 0x00f0f0f0) >> 4) | ((add1 & 0x000f0f0f) << 4);
add1 = ((add1 & 0x00cccccc) >> 2) | ((add1 & 0x00333333) << 2);
add1 = ((add1 & 0x00aaaaaa) >> 1) | ((add1 & 0x00555555) << 1);
#ifdef GT_DEBUG
printk("eaddr= %s add1:%x add0:%x\n", ether_sprintf1(eaddr), add1, add0);
#endif
/*
* hashResult is the 15 bits Hash entry address.
* ethernetADD is a 48 bit number, which is derived from the Ethernet
* MAC address, by nibble swapping in every byte (i.e MAC address
* of 0x123456789abc translates to ethernetADD of 0x21436587a9cb).
*/
if ((sc->sc_pcr & ETH_EPCR_HM) == 0) {
/*
* hashResult[14:0] = hashFunc0(ethernetADD[47:0])
*
* hashFunc0 calculates the hashResult in the following manner:
* hashResult[ 8:0] = ethernetADD[14:8,1,0]
* XOR ethernetADD[23:15] XOR ethernetADD[32:24]
*/
result = (add0 & 3) | ((add0 >> 6) & ~3);
result ^= (add0 >> 15) ^ (add1 >> 0);
result &= 0x1ff;
/*
* hashResult[14:9] = ethernetADD[7:2]
*/
result |= (add0 & ~3) << 7; /* excess bits will be masked */
#ifdef GT_DEBUG
printk("hash result %x ", result & 0x7fff);
#endif
} else {
#define TRIBITFLIP 073516240 /* yes its in octal */
/*
* hashResult[14:0] = hashFunc1(ethernetADD[47:0])
*
* hashFunc1 calculates the hashResult in the following manner:
* hashResult[08:00] = ethernetADD[06:14]
* XOR ethernetADD[15:23] XOR ethernetADD[24:32]
*/
w0 = ((add0 >> 6) ^ (add0 >> 15) ^ (add1)) & 0x1ff;
/*
* Now bitswap those 9 bits
*/
result = 0;
result |= ((TRIBITFLIP >> (((w0 >> 0) & 7) * 3)) & 7) << 6;
result |= ((TRIBITFLIP >> (((w0 >> 3) & 7) * 3)) & 7) << 3;
result |= ((TRIBITFLIP >> (((w0 >> 6) & 7) * 3)) & 7) << 0;
/*
* hashResult[14:09] = ethernetADD[00:05]
*/
result |= ((TRIBITFLIP >> (((add0 >> 0) & 7) * 3)) & 7) << 12;
result |= ((TRIBITFLIP >> (((add0 >> 3) & 7) * 3)) & 7) << 9;
#ifdef GT_DEBUG
printk("1(%#x)", result);
#endif
}
#ifdef GT_DEBUG
printk(")");
#endif
/* 1/2K address filtering (MOTLoad default )? ->16KB memory required
* or 8k address filtering ? -> 256KB memory required
*/
return result & ((sc->sc_pcr & ETH_EPCR_HS_512) ? 0x7ff : 0x7fff);
}
static int GTeth_hash_entry_op(struct GTeth_softc *sc, enum GTeth_hash_op op,
enum GTeth_rxprio prio,unsigned char eaddr[ETHER_ADDR_LEN])
{
unsigned long long he;
unsigned long long *maybe_he_p = NULL;
int limit;
int hash;
int maybe_hash = 0;
#ifdef GT_DEBUG
printk("GTeth_hash_entry_op(prio %d ", prio);
#endif
hash = GTeth_hash_compute(sc, eaddr);
if (sc->sc_hashtable == NULL) {
printk("hashtable == NULL!");
}
#ifdef GT_DEBUG
printk("Hash computed %x eaddr %s\n", hash,ether_sprintf1(eaddr));
#endif
/*
* Assume we are going to insert so create the hash entry we
* are going to insert. We also use it to match entries we
* will be removing. The datasheet is wrong for this.
*/
he = (((unsigned long long) eaddr[5]) << 43) |
(((unsigned long long) eaddr[4]) << 35) |
(((unsigned long long) eaddr[3]) << 27) |
(((unsigned long long) eaddr[2]) << 19) |
(((unsigned long long) eaddr[1]) << 11) |
(((unsigned long long) eaddr[0]) << 3) |
((unsigned long long) HSH_PRIO_INS(prio) | HSH_V | HSH_R);
/* he = 0x1b1acd87d08005;*/
/*
* The GT will search upto 12 entries for a hit, so we must mimic that.
*/
hash &= (sc->sc_hashmask / sizeof(he));
#ifdef GT_DEBUG
if (GTeth_debug>0) {
unsigned val1, val2;
val1= he & 0xffffffff;
val2= (he >>32) & 0xffffffff;
printk("Hash addr value %x%x, entry %x\n",val2,val1, hash);
}
#endif
for (limit = HSH_LIMIT; limit > 0 ; --limit) {
/*
* Does the GT wrap at the end, stop at the, or overrun the
* end? Assume it wraps for now. Stash a copy of the
* current hash entry.
*/
unsigned long long *he_p = &sc->sc_hashtable[hash];
unsigned long long thishe = *he_p;
/*
* If the hash entry isn't valid, that break the chain. And
* this entry a good candidate for reuse.
*/
if ((thishe & HSH_V) == 0) {
maybe_he_p = he_p;
break;
}
/*
* If the hash entry has the same address we are looking for
* then ... if we are removing and the skip bit is set, its
* already been removed. if are adding and the skip bit is
* clear, then its already added. In either return EBUSY
* indicating the op has already been done. Otherwise flip
* the skip bit and return 0.
*/
if (((he ^ thishe) & HSH_ADDR_MASK) == 0) {
if (((op == GE_HASH_REMOVE) && (thishe & HSH_S)) ||
((op == GE_HASH_ADD) && (thishe & HSH_S) == 0))
return EBUSY;
*he_p = thishe ^ HSH_S;
if (GTeth_debug>0) {
unsigned val1, val2;
val1= *he_p & 0xffffffff;
val2= (*he_p >>32) & 0xffffffff;
printk("flip skip bit result %x%x entry %x ",val2,val1, hash);
}
return 0;
}
/*
* If we haven't found a slot for the entry and this entry
* is currently being skipped, return this entry.
*/
if (maybe_he_p == NULL && (thishe & HSH_S)) {
maybe_he_p = he_p;
maybe_hash = hash;
}
hash = (hash + 1) & (sc->sc_hashmask / sizeof(he));
}
/*
* If we got here, then there was no entry to remove.
*/
if (op == GE_HASH_REMOVE) {
printk("GT64260eth : No entry to remove\n");
return ENOENT;
}
/*
* If we couldn't find a slot, return an error.
*/
if (maybe_he_p == NULL) {
printk("GT64260eth : No slot found");
return ENOSPC;
}
/* Update the entry.*/
*maybe_he_p = he;
if (GTeth_debug>0) {
unsigned val1, val2;
#if 0
unsigned long *pt= sc->sc_hashtable;
int i, loop;
for (loop= 0; loop< 256; loop++) {
printk("%d)", loop);
for (i=0; i< 16; i++, pt++) printk("%x ",*pt);
printk("\n");
}
#endif
val1= he & 0xffffffff;
val2= (he >>32) & 0xffffffff;
printk("Update Hash result %x%x, table addr %x entry %x )\n",val2, val1, maybe_he_p, hash);
}
return 0;
}
static int GTeth_hash_fill(struct GTeth_softc *sc)
{
struct ether_multistep step;
struct ether_multi *enm;
int error;
#ifdef GT_DEBUG
printk( "GTeth_hash_fill(");
#endif
error = GTeth_hash_entry_op(sc,GE_HASH_ADD,GE_RXPRIO_HI,sc->arpcom.ac_enaddr);
if (error) {
if (GTeth_debug>0) printk("!");
return error;
}
sc->sc_flags &= ~GE_ALLMULTI;
if ((sc->arpcom.ac_if.if_flags & IFF_PROMISC) == 0)
sc->sc_pcr &= ~ETH_EPCR_PM;
/* see lib/include/netinet/if_ether.h */
ETHER_FIRST_MULTI(step, &sc->arpcom, enm);
while (enm != NULL) {
if (memcmp(enm->enm_addrlo, enm->enm_addrhi, ETHER_ADDR_LEN)) {
/* Frames are received regardless of their destinatin address */
sc->sc_flags |= GE_ALLMULTI;
sc->sc_pcr |= ETH_EPCR_PM;
} else {
/* Frames are only received if the destinatin address is found
* in the hash table
*/
error = GTeth_hash_entry_op(sc, GE_HASH_ADD,
GE_RXPRIO_MEDLO, enm->enm_addrlo);
if (error == ENOSPC) break;
}
ETHER_NEXT_MULTI(step, enm);
}
#ifdef GT_DEBUG
printk(")\n");
#endif
return error;
}
static void GTeth_hash_init(struct GTeth_softc *sc)
{
void *hash_mem;
if (GTeth_debug>0) printk("GTeth_hash_init(");
/* MOTLoad defualt : 512 bytes of address filtering, which
* requires 16KB of memory
*/
#if 1
hash_mem = rtems_bsdnet_malloc(HASH_DRAM_SIZE + HASH_ALIGN, M_FREE, M_NOWAIT);
sc->sc_hashtable =(void *)(((long)hash_mem+ HASH_ALIGN) & ~HASH_ALIGN);
#else
/* only for test */
hash_mem = 0x68F000;
sc->sc_hashtable =(unsigned long long *)hash_mem;
#endif
sc->sc_hashmask = HASH_DRAM_SIZE - 1;
memset((void *)sc->sc_hashtable, 0,HASH_DRAM_SIZE);
#ifdef GT_DEBUG
printk("hashtable addr:%x, mask %x)\n", sc->sc_hashtable,sc->sc_hashmask);
#endif
}
#ifdef GT64260eth_DEBUG
static void GT64260eth_error(struct GTeth_softc *sc)
{
struct ifnet *ifp = &sc->arpcom.ac_if;
unsigned int intr_status= sc->intr_errsts[sc->intr_err_ptr1];
/* read and reset the status; because this is written
* by the ISR, we must disable interrupts here
*/
if (intr_status) {
printk("%s%d: ICR = 0x%x ",
ifp->if_name, ifp->if_unit, intr_status);
#if 1
if (intr_status & INTR_RX_ERROR) {
printk("Rxq error, if_ierrors %d\n",
ifp->if_ierrors);
}
#endif
/* Rx error is handled in GT64260eth_rx() */
if (intr_status & INTR_TX_ERROR) {
ifp->if_oerrors++;
printk("Txq error, if_oerrors %d\n",ifp->if_oerrors);
}
}
else
printk("%s%d: Ghost interrupt ?\n",ifp->if_name,
ifp->if_unit);
sc->intr_errsts[sc->intr_err_ptr1++]=0;
sc->intr_err_ptr1 %= INTR_ERR_SIZE; /* Till Straumann */
}
#endif
/* The daemon does all of the work; RX, TX and cleaning up buffers/descriptors */
static void GT64260eth_daemon(void *arg)
{
struct GTeth_softc *sc = (struct GTeth_softc*)arg;
rtems_event_set events;
struct mbuf *m=0;
struct ifnet *ifp=&sc->arpcom.ac_if;
#if 0
/* see comments in GT64260eth_init(); in newer versions of
* rtems, we hold the network semaphore at this point
*/
rtems_semaphore_release(sc->daemonSync);
#endif
/* NOTE: our creator possibly holds the bsdnet_semaphore.
* since that has PRIORITY_INVERSION enabled, our
* subsequent call to bsdnet_event_receive() will
* _not_ release it. It's still in posession of our
* owner.
* This is different from how killing this task
* is handled.
*/
for (;;) {
/* sleep until there's work to be done */
/* Note: bsdnet_event_receive() acquires
* the global bsdnet semaphore for
* mutual exclusion.
*/
rtems_bsdnet_event_receive(ALL_EVENTS,
RTEMS_WAIT | RTEMS_EVENT_ANY,
RTEMS_NO_TIMEOUT,
&events);
if (KILL_EVENT & events) break;
#ifndef GE_NORX
if (events & RX_EVENT) GT64260eth_rx(sc);
#endif
#if 0
printk("%x ", inb(ETH0_EPSR));
if ( ((i++) % 15)==0) printk("\n");
#endif
/* clean up and try sending packets */
do {
if (sc->txq_nactive) GTeth_txq_done(sc);
while (sc->txq_free>0) {
if (sc->txq_free>TXQ_HiLmt_OFF) {
m=0;
IF_DEQUEUE(&ifp->if_snd,m);
if (m==0) break;
GT64260eth_sendpacket(sc, m);
}
else {
GTeth_txq_done(sc);
break;
}
}
/* we leave this loop
* - either because there's no free buffer
* (m=0 initializer && !sc->txq_free)
* - or there's nothing to send (IF_DEQUEUE
* returned 0
*/
} while (m);
ifp->if_flags &= ~IFF_OACTIVE;
/* Log errors and other uncommon events. */
#ifdef GT64260eth_DEBUG
if (events & ERR_EVENT) GT64260eth_error(sc);
#endif
} /* end for(;;) { rtems_bsdnet_event_receive() .....*/
ifp->if_flags &= ~(IFF_RUNNING|IFF_OACTIVE);
/* shut down the hardware */
GT64260eth_stop_hw(sc);
/* flush the output queue */
for (;;) {
IF_DEQUEUE(&ifp->if_snd,m);
if (!m) break;
m_freem(m);
}
/* as of 'rtems_bsdnet_event_receive()' we own the
* networking semaphore
*/
rtems_bsdnet_semaphore_release();
rtems_semaphore_release(sc->daemonSync);
/* Note that I dont use sc->daemonTid here -
* theoretically, that variable could already
* hold a newly created TID
*/
rtems_task_delete(RTEMS_SELF);
}