ref: f0f2d452c873255dec4b3359b3f93e349be0f2c5
dir: /sys/src/9/imx8/etherimx.c/
#include "u.h"
#include "../port/lib.h"
#include "mem.h"
#include "dat.h"
#include "fns.h"
#include "io.h"
#include "../port/netif.h"
#include "../port/etherif.h"
#include "../port/ethermii.h"
enum {
Ptpclk = 100*Mhz,
Busclk = 266*Mhz,
Txclk = 125*Mhz,
Maxtu = 1518,
R_BUF_SIZE = ((Maxtu+BLOCKALIGN-1)&~BLOCKALIGN),
};
enum {
ENET_EIR = 0x004/4, /* Interrupt Event Register */
ENET_EIMR = 0x008/4, /* Interrupt Mask Register */
INT_BABR =1<<30, /* Babbling Receive Error */
INT_BABT =1<<31, /* Babbling Transmit Error */
INT_GRA =1<<28, /* Graceful Stop Complete */
INT_TXF =1<<27, /* Transmit Frame Interrupt */
INT_TXB =1<<26, /* Transmit Buffer Interrupt */
INT_RXF =1<<25, /* Receive Frame Interrupt */
INT_RXB =1<<24, /* Receive Buffer Interrupt */
INT_MII =1<<23, /* MII Interrupt */
INT_EBERR =1<<22, /* Ethernet Bus Error */
INT_LC =1<<21, /* Late Collision */
INT_RL =1<<20, /* Collision Retry Limit */
INT_UN =1<<19, /* Transmit FIFO Underrun */
INT_PLR =1<<18, /* Payload Receive Error */
INT_WAKEUP =1<<17, /* Node Wakeup Request Indication */
INT_TS_AVAIL =1<<16, /* Transmit Timestamp Available */
INT_TS_TIMER =1<<15, /* Timestamp Timer */
INT_RXFLUSH_2 =1<<14, /* RX DMA Ring 2 flush indication */
INT_RXFLUSH_1 =1<<13, /* RX DMA Ring 1 flush indication */
INT_RXFLUSH_0 =1<<12, /* RX DMA Ring 0 flush indication */
INT_TXF2 =1<<7, /* Transmit frame interrupt, class 2 */
INT_TXB2 =1<<6, /* Transmit buffer interrupt, class 2 */
INT_RXF2 =1<<5, /* Receive frame interrupt, class 2 */
INT_RXB2 =1<<4, /* Receive buffer interrupt, class 2 */
INT_TXF1 =1<<3, /* Transmit frame interrupt, class 1 */
INT_TXB1 =1<<2, /* Transmit buffer interrupt, class 1 */
INT_RXF1 =1<<1, /* Receive frame interrupt, class 1 */
INT_RXB1 =1<<0, /* Receive buffer interrupt, class 1 */
ENET_RDAR = 0x010/4, /* Receive Descriptor Active Register */
RDAR_ACTIVE =1<<24, /* Descriptor Active */
ENET_TDAR = 0x014/4, /* Transmit Descriptor Active Register */
TDAR_ACTIVE =1<<24, /* Descriptor Active */
ENET_ECR = 0x024/4, /* Ethernet Control Register */
ECR_RESERVED =7<<28,
ECR_SVLANDBL =1<<11, /* S-VLAN double tag */
ECR_VLANUSE2ND =1<<10, /* VLAN use second tag */
ECR_SVLANEN =1<<9, /* S-VLAN enable */
ECR_DBSWP =1<<8, /* Descriptor Byte Swapping Enable */
ECR_DBGEN =1<<6, /* Debug Enable */
ECR_SPEED_100M =0<<5,
ECR_SPEED_1000M =1<<5,
ECR_EN1588 =1<<4, /* Enables enhanced functionality of the MAC */
ECR_SLEEP =1<<3, /* Sleep Mode Enable */
ECR_MAGICEN =1<<2, /* Magic Packet Detection Enable */
ECR_ETHEREN =1<<1, /* Ethernet Enable */
ECR_RESET =1<<0, /* Ethernet MAC Reset */
ENET_MMFR = 0x040/4, /* MII Management Frame Register */
MMFR_ST =1<<30,
MMFR_RD =2<<28,
MMFR_WR =1<<28,
MMFR_PA_SHIFT =23,
MMFR_TA =2<<16,
MMFR_RA_SHIFT =18,
ENET_MSCR = 0x044/4, /* MII Speed Control Register */
MSCR_SPEED_SHIFT=1, /* MII speed = module_clock/((SPEED+1)*2) */
MSCR_DIS_PRE =1<<7, /* disable preamble */
MSCR_HOLD_SHIFT =8, /* hold cycles in module_clock */
ENET_MIBC = 0x064/4, /* MIB Control Register */
ENET_RCR = 0x084/4, /* Receive Control Register */
RCR_GRS =1<<31, /* Gracefull Receive Stopped */
RCR_NLC =1<<30, /* Payload Length Check Disable */
RCR_MAX_FL_SHIFT=16, /* Maximum Frame Length */
RCR_CFEN =1<<15, /* MAC Control Frame Enable */
RCR_CRCFWD =1<<14, /* Forward Received CRC */
RCR_PAUFWD =1<<13, /* Forward Pause Frames */
RCR_PADEN =1<<12, /* Enable Frame Padding Remove */
RCR_RMII_10T =1<<9, /* Enables 10-Mbit/s mode of the RMII/RGMII */
RCR_RMII_MODE =1<<8, /* RMII Mode Enable */
RCR_RGMII_EN =1<<6, /* RGMII Mode Enable */
RCR_FCE =1<<5, /* Flow Control Enable */
RCR_REJ =1<<4, /* Broadcast Frame Reject */
RCR_PROM =1<<3, /* Promiscuous Mode */
RCR_MII_MODE =1<<2, /* Media Independent Interface Mode (must always be set) */
RCR_DRT =1<<1, /* Disable Receive On Timeout */
RCR_LOOP =1<<0, /* Internal Loopback */
ENET_TCR = 0x0C4/4, /* Transmit Control Register */
TCR_CRCFWD =1<<9, /* Foward Frame From Application With CRC */
TCR_ADDINS =1<<8, /* Set MAC Address on Transmit */
TCR_RFC_PAUSE =1<<4, /* Receive Frame Control Pause */
TCR_TFC_PAUSE =1<<3, /* Transmit Frame Control Pause */
TCR_FDEN =1<<2, /* Full-Duplex Enable */
TCR_GTS =1<<0, /* Graceful Transmit Stop */
ENET_PALR = 0x0E4/4, /* Physical Address Lower Register */
ENET_PAUR = 0x0E8/4, /* Physical Address Upper Register */
ENET_OPD = 0x0EC/4, /* Opcode/Pause Duration Register */
ENET_TXIC0 = 0x0F0/4, /* Transmit Interrupt Coalescing Register */
ENET_TXIC1 = 0x0F4/4, /* Transmit Interrupt Coalescing Register */
ENET_TXIC2 = 0x0F8/4, /* Transmit Interrupt Coalescing Register */
ENET_RXIC0 = 0x100/4, /* Receive Interrupt Coalescing Register */
ENET_RXIC1 = 0x104/4, /* Receive Interrupt Coalescing Register */
ENET_RXIC2 = 0x108/4, /* Receive Interrupt Coalescing Register */
IC_EN = 1<<31,
IC_CS = 1<<30,
IC_FT_SHIFT = 20,
IC_TT_SHIFT = 0,
ENET_IAUR = 0x118/4, /* Descriptor Individual Upper Address Register */
ENET_IALR = 0x11C/4, /* Descriptor Individual Lower Address Register */
ENET_GAUR = 0x120/4, /* Descriptor Group Upper Address Register */
ENET_GALR = 0x124/4, /* Descriptor Group Lower Address Register */
ENET_TFWR = 0x144/4, /* Transmit FIFO Watermark Register */
TFWR_STRFWD = 1<<8,
ENET_RDSR1 = 0x160/4, /* Receive Descriptor Ring 1 Start Register */
ENET_TDSR1 = 0x164/4, /* Transmit Buffer Descriptor Ring 1 Start Register */
ENET_MRBR1 = 0x168/4, /* Maximum Receive Buffer Size Register Ring 1 */
ENET_RDSR2 = 0x16C/4, /* Receive Descriptor Ring 2 Start Register */
ENET_TDSR2 = 0x170/4, /* Transmit Buffer Descriptor Ring 2 Start Register */
ENET_MRBR2 = 0x174/4, /* Maximum Receive Buffer Size Register Ring 2 */
ENET_RDSR = 0x180/4, /* Receive Descriptor Ring 0 Start Register */
ENET_TDSR = 0x184/4, /* Transmit Buffer Descriptor Ring 0 Start Register */
ENET_MRBR = 0x188/4, /* Maximum Receive Buffer Size Register Ring 0 */
ENET_RSFL = 0x190/4, /* Receive FIFO Section Full Threshold */
ENET_RSEM = 0x194/4, /* Receive FIFO Section Empty Threshold */
ENET_RAEM = 0x198/4, /* Receive FIFO Almost Empty Threshold */
ENET_RAFL = 0x19C/4, /* Receive FIFO Almost Full Threshold */
ENET_TSEM = 0x1A0/4, /* Transmit FIFO Section Empty Threshold */
ENET_TAEM = 0x1A4/4, /* Transmit FIFO Almost Empty Threshold */
ENET_TAFL = 0x1A8/4, /* Transmit FIFO Almost Full Threshold */
ENET_TIPG = 0x1AC/4, /* Transmit Inter-Packet Gap */
ENET_FTRL = 0x1B0/4, /* Frame Truncation Length */
ENET_TACC = 0x1C0/4, /* Transmit Accelerator Function Configuration */
ENET_RACC = 0x1C4/4, /* Receive Accelerator Function Configuration */
ENET_RCMR1 = 0x1C8/4, /* Receive Classification Match Register */
ENET_RCMR2 = 0x1CC/4, /* Receive Classification Match Register */
ENET_DMA1CFG = 0x1D8/4, /* DMA Class Based Configuration */
ENET_DMA2CFG = 0x1DC/4, /* DMA Class Based Configuration */
ENET_RDAR1 = 0x1E0/4, /* Receive Descriptor Active Register - Ring 1 */
ENET_TDAR1 = 0x1E4/4, /* Transmit Descriptor Active Register - Ring 1 */
ENET_RDAR2 = 0x1E8/4, /* Receive Descriptor Active Register - Ring 2 */
ENET_TDAR2 = 0x1EC/4, /* Transmit Descriptor Active Register - Ring 2 */
ENET_QOS = 0x1F0/4, /* QOS Scheme */
};
enum {
/* transmit descriptor status bits */
TD_R = 1<<(15+16), /* Ready */
TD_OWN = 1<<(14+16), /* Ownership */
TD_W = 1<<(13+16), /* Wrap */
TD_L = 1<<(11+16), /* Last in a frame */
TD_TC = 1<<(10+16), /* Transmit CRC */
TD_ERR = TD_TC,
TD_LEN = 0xFFFF,
/* receive desctriptor status bits */
RD_E = 1<<(15+16), /* Empty */
RD_W = 1<<(13+16), /* Wrap */
RD_L = 1<<(11+16), /* Last in a frame */
RD_M = 1<<(8+16), /* Miss */
RD_BC = 1<<(7+16), /* broadcast */
RD_MC = 1<<(6+16), /* multicast */
RD_LG = 1<<(5+16), /* length violation */
RD_NO = 1<<(4+16), /* non octet aligned frame */
RD_CR = 1<<(2+16), /* crc error */
RD_OV = 1<<(1+16), /* overrun */
RD_TR = 1<<(0+16), /* truncated */
RD_ERR = RD_LG | RD_NO | RD_CR | RD_OV | RD_TR,
RD_LEN = 0xFFFF,
};
typedef struct Descr Descr;
struct Descr
{
u32int status;
u32int addr;
};
typedef struct Ctlr Ctlr;
struct Ctlr
{
u32int *regs;
u32int intmask;
struct {
Block *b[256];
Descr *d;
Rendez;
} rx[1];
struct {
Block *b[256];
Descr *d;
Rendez;
} tx[1];
struct {
Rendez;
} free[1];
struct {
Mii;
int done;
Rendez;
} mii[1];
int attached;
QLock;
};
#define rr(c, r) ((c)->regs[r])
#define wr(c, r, v) ((c)->regs[r] = (v))
static int
mdiodone(void *arg)
{
Ctlr *ctlr = arg;
return ctlr->mii->done || (rr(ctlr, ENET_EIR) & INT_MII) != 0;
}
static int
mdiowait(Ctlr *ctlr)
{
int i;
for(i = 0; i < 200; i++){
tsleep(ctlr->mii, mdiodone, ctlr, 5);
if(mdiodone(ctlr))
return 0;
}
return -1;
}
static int
mdiow(Mii* mii, int phy, int addr, int data)
{
Ctlr *ctlr = mii->ctlr;
data &= 0xFFFF;
wr(ctlr, ENET_EIR, INT_MII);
ctlr->mii->done = 0;
wr(ctlr, ENET_MMFR, MMFR_WR | MMFR_ST | MMFR_TA | phy<<MMFR_PA_SHIFT | addr<<MMFR_RA_SHIFT | data);
if(mdiowait(ctlr) < 0)
return -1;
return data;
}
static int
mdior(Mii* mii, int phy, int addr)
{
Ctlr *ctlr = mii->ctlr;
wr(ctlr, ENET_EIR, INT_MII);
ctlr->mii->done = 0;
wr(ctlr, ENET_MMFR, MMFR_RD | MMFR_ST | MMFR_TA | phy<<MMFR_PA_SHIFT | addr<<MMFR_RA_SHIFT);
if(mdiowait(ctlr) < 0)
return -1;
return rr(ctlr, ENET_MMFR) & 0xFFFF;
}
static void
interrupt(Ureg*, void *arg)
{
Ether *edev = arg;
Ctlr *ctlr = edev->ctlr;
u32int e;
e = rr(ctlr, ENET_EIR);
if(e & INT_RXF) wakeup(ctlr->rx);
if(e & INT_TXF) wakeup(ctlr->tx);
if(e & INT_MII) {
ctlr->mii->done = 1;
wakeup(ctlr->mii);
}
wr(ctlr, ENET_EIR, e);
}
static void
shutdown(Ether *edev)
{
Ctlr *ctlr = edev->ctlr;
coherence();
wr(ctlr, ENET_ECR, ECR_RESERVED | ECR_RESET);
while(rr(ctlr, ENET_ECR) & ECR_RESET) delay(1);
/* mask and clear interrupt events */
wr(ctlr, ENET_EIMR, 0);
wr(ctlr, ENET_EIR, ~0);
}
static int
tdfree(void *arg)
{
Descr *d = arg;
return (d->status & (TD_OWN|TD_R)) == 0;
}
static void
txproc(void *arg)
{
Ether *edev = arg;
Ctlr *ctlr = edev->ctlr;
Block *b;
Descr *d;
uint i = 0;
while(waserror())
;
for(;;){
if((b = qbread(edev->oq, 100000)) == nil)
break;
d = &ctlr->tx->d[i];
while(!tdfree(d))
sleep(ctlr->free, tdfree, d);
ctlr->tx->b[i] = b;
dmaflush(1, b->rp, BLEN(b));
d->addr = PADDR(b->rp);
coherence();
if(i == nelem(ctlr->tx->b)-1){
d->status = BLEN(b) | TD_OWN | TD_R | TD_L | TD_TC | TD_W;
i = 0;
} else {
d->status = BLEN(b) | TD_OWN | TD_R | TD_L | TD_TC;
i++;
}
wr(ctlr, ENET_TDAR, TDAR_ACTIVE);
}
}
static int
tddone(void *arg)
{
Descr *d = arg;
return (d->status & (TD_OWN|TD_R)) == TD_OWN;
}
static void
frproc(void *arg)
{
Ether *edev = arg;
Ctlr *ctlr = edev->ctlr;
Block *b;
Descr *d;
uint i = 0;
while(waserror())
;
for(;;){
d = &ctlr->tx->d[i];
while(!tddone(d))
sleep(ctlr->tx, tddone, d);
b = ctlr->tx->b[i];
ctlr->tx->b[i] = nil;
coherence();
if(i == nelem(ctlr->tx->b)-1){
d->status = TD_W;
i = 0;
} else {
d->status = 0;
i++;
}
wakeup(ctlr->free);
freeb(b);
}
}
static int
rdfull(void *arg)
{
Descr *d = arg;
return (d->status & RD_E) == 0;
}
static void
rxproc(void *arg)
{
Ether *edev = arg;
Ctlr *ctlr = edev->ctlr;
Block *b;
Descr *d;
uint s, i = 0;
while(waserror())
;
for(;;){
d = &ctlr->rx->d[i];
s = d->status;
if(s & RD_E){
sleep(ctlr->rx, rdfull, d);
continue;
}
if(((s^RD_L) & (RD_L|RD_ERR)) == 0){
b = ctlr->rx->b[i];
b->wp = b->rp + (s & RD_LEN) - 4;
dmaflush(0, b->rp, BLEN(b));
etheriq(edev, b);
/* replenish */
b = allocb(R_BUF_SIZE);
ctlr->rx->b[i] = b;
dmaflush(1, b->rp, R_BUF_SIZE);
d->addr = PADDR(b->rp);
coherence();
}
if(i == nelem(ctlr->rx->b)-1) {
d->status = RD_E | RD_W;
i = 0;
} else {
d->status = RD_E;
i++;
}
wr(ctlr, ENET_RDAR, RDAR_ACTIVE);
}
}
static void
linkproc(void *arg)
{
Ether *edev = arg;
Ctlr *ctlr = edev->ctlr;
MiiPhy *phy;
int link = 0;
while(waserror())
;
miiane(ctlr->mii, ~0, ~0, ~0);
for(;;){
miistatus(ctlr->mii);
phy = ctlr->mii->curphy;
if(phy->link == link){
tsleep(ctlr->mii, return0, nil, 5000);
continue;
}
link = phy->link;
if(link){
u32int ecr = rr(ctlr, ENET_ECR) & ~ECR_SPEED_1000M;
u32int rcr = rr(ctlr, ENET_RCR) & ~(RCR_RMII_10T|RCR_FCE);
u32int tcr = rr(ctlr, ENET_TCR) & ~(TCR_RFC_PAUSE|TCR_TFC_PAUSE|TCR_FDEN);
switch(phy->speed){
case 1000:
ecr |= ECR_SPEED_1000M;
rcr |= RCR_FCE;
/* receive fifo thresholds */
wr(ctlr, ENET_RSFL, 16);
wr(ctlr, ENET_RSEM, 132);
wr(ctlr, ENET_RAEM, 8);
wr(ctlr, ENET_RAFL, 8);
/* opcode/pause duration */
wr(ctlr, ENET_OPD, 0xFFF0);
break;
case 100:
ecr |= ECR_SPEED_100M;
break;
case 10:
rcr |= RCR_RMII_10T;
break;
}
if(phy->fd)
tcr |= TCR_FDEN;
if(phy->rfc)
tcr |= TCR_RFC_PAUSE;
if(phy->tfc)
tcr |= TCR_TFC_PAUSE;
wr(ctlr, ENET_ECR, ecr);
wr(ctlr, ENET_RCR, rcr);
wr(ctlr, ENET_TCR, tcr);
edev->mbps = phy->speed;
wr(ctlr, ENET_RDAR, RDAR_ACTIVE);
}
edev->link = link;
print("#l%d: link %d speed %d\n", edev->ctlrno, edev->link, edev->mbps);
}
}
static void
attach(Ether *edev)
{
Ctlr *ctlr = edev->ctlr;
Descr *d;
int i;
eqlock(ctlr);
if(ctlr->attached){
qunlock(ctlr);
return;
}
if(waserror()){
qunlock(ctlr);
nexterror();
}
/* RGMII mode, max frame length */
wr(ctlr, ENET_RCR, RCR_MII_MODE | RCR_RGMII_EN | Maxtu<<RCR_MAX_FL_SHIFT);
/* set MII clock to 2.5Mhz, 10ns hold time */
wr(ctlr, ENET_MSCR, ((Busclk/(2*2500000))-1)<<MSCR_SPEED_SHIFT | ((Busclk/1000000)-1)<<MSCR_HOLD_SHIFT);
ctlr->intmask |= INT_MII;
wr(ctlr, ENET_EIMR, ctlr->intmask);
mii(ctlr->mii, ~0);
if(ctlr->mii->curphy == nil)
error("no phy");
print("#l%d: phy%d id %.8ux oui %x\n",
edev->ctlrno, ctlr->mii->curphy->phyno,
ctlr->mii->curphy->id, ctlr->mii->curphy->oui);
/* clear mac filter hash table */
wr(ctlr, ENET_IALR, 0);
wr(ctlr, ENET_IAUR, 0);
wr(ctlr, ENET_GALR, 0);
wr(ctlr, ENET_GAUR, 0);
/* set MAC address */
wr(ctlr, ENET_PALR, (u32int)edev->ea[0]<<24 | (u32int)edev->ea[1]<<16 | (u32int)edev->ea[2]<<8 | edev->ea[3]<<0);
wr(ctlr, ENET_PAUR, (u32int)edev->ea[4]<<24 | (u32int)edev->ea[5]<<16);
if(ctlr->rx->d == nil)
ctlr->rx->d = ucalloc(sizeof(Descr) * nelem(ctlr->rx->b));
for(i=0; i<nelem(ctlr->rx->b); i++){
Block *b = allocb(R_BUF_SIZE);
ctlr->rx->b[i] = b;
d = &ctlr->rx->d[i];
dmaflush(1, b->rp, R_BUF_SIZE);
d->addr = PADDR(b->rp);
d->status = RD_E;
}
ctlr->rx->d[nelem(ctlr->rx->b)-1].status = RD_E | RD_W;
wr(ctlr, ENET_MRBR, R_BUF_SIZE);
coherence();
wr(ctlr, ENET_RDSR, PADDR(ctlr->rx->d));
if(ctlr->tx->d == nil)
ctlr->tx->d = ucalloc(sizeof(Descr) * nelem(ctlr->tx->b));
for(i=0; i<nelem(ctlr->tx->b); i++){
ctlr->tx->b[i] = nil;
d = &ctlr->tx->d[i];
d->addr = 0;
d->status = 0;
}
ctlr->tx->d[nelem(ctlr->tx->b)-1].status = TD_W;
coherence();
wr(ctlr, ENET_TDSR, PADDR(ctlr->tx->d));
/* store and forward tx fifo */
wr(ctlr, ENET_TFWR, TFWR_STRFWD);
/* interrupt coalescing: 200 pkts, 1000 µs */
wr(ctlr, ENET_RXIC0, IC_EN | 200<<IC_FT_SHIFT | ((1000*Txclk)/64000000)<<IC_TT_SHIFT);
wr(ctlr, ENET_TXIC0, IC_EN | 200<<IC_FT_SHIFT | ((1000*Txclk)/64000000)<<IC_TT_SHIFT);
ctlr->intmask |= INT_TXF | INT_RXF;
wr(ctlr, ENET_EIMR, ctlr->intmask);
/* enable ethernet */
wr(ctlr, ENET_ECR, rr(ctlr, ENET_ECR) | ECR_ETHEREN | ECR_DBSWP);
ctlr->attached = 1;
kproc("ether-rx", rxproc, edev);
kproc("ether-tx", txproc, edev);
kproc("ether-fr", frproc, edev);
kproc("ether-link", linkproc, edev);
qunlock(ctlr);
poperror();
}
static void
prom(void *arg, int on)
{
Ether *edev = arg;
Ctlr *ctlr = edev->ctlr;
if(on)
wr(ctlr, ENET_RCR, rr(ctlr, ENET_RCR) | RCR_PROM);
else
wr(ctlr, ENET_RCR, rr(ctlr, ENET_RCR) & ~RCR_PROM);
}
static void
multi(void *arg, uchar*, int)
{
Ether *edev = arg;
Ctlr *ctlr = edev->ctlr;
Netaddr *a;
u64int hash;
hash = 0;
for(a = edev->maddr; a != nil; a = a->next)
hash |= 1ULL << ((ethercrc(a->addr, edev->alen) >> (32 - 6)) & 0x3F);
wr(ctlr, ENET_GALR, hash & 0xFFFFFFFF);
wr(ctlr, ENET_GAUR, hash >> 32);
}
static long
ctl(Ether*, void*, long len)
{
return len;
}
static int
reset(Ether *edev)
{
enum {
OCOTP_HW_OCOTP_MAC_ADDR0 = 0x640/4,
OCOTP_HW_OCOTP_MAC_ADDR1 = 0x650/4,
};
static u32int *ocotp = (u32int*)(VIRTIO + 0x350000);
u32int a0, a1;
a0 = ocotp[OCOTP_HW_OCOTP_MAC_ADDR0];
a1 = ocotp[OCOTP_HW_OCOTP_MAC_ADDR1];
edev->ea[0] = a1>>8;
edev->ea[1] = a1>>0;
edev->ea[2] = a0>>24;
edev->ea[3] = a0>>16;
edev->ea[4] = a0>>8;
edev->ea[5] = a0>>0;
shutdown(edev);
return 0;
}
static int
pnp(Ether *edev)
{
static Ctlr ctlr[1];
if(ctlr->regs != nil)
return -1;
ctlr->regs = (u32int*)(VIRTIO + 0xbe0000);
ctlr->mii->ctlr = ctlr;
ctlr->mii->mir = mdior;
ctlr->mii->miw = mdiow;
edev->port = (uintptr)ctlr->regs - KZERO;
edev->irq = IRQenet1;
edev->ctlr = ctlr;
edev->attach = attach;
edev->shutdown = shutdown;
edev->promiscuous = prom;
edev->multicast = multi;
edev->ctl = ctl;
edev->arg = edev;
edev->mbps = 1000;
edev->maxmtu = Maxtu;
iomuxpad("pad_enet_mdc", "enet1_mdc", "~LVTTL ~HYS ~PUE ~ODE SLOW 75_OHM");
iomuxpad("pad_enet_mdio", "enet1_mdio", "~LVTTL ~HYS ~PUE ODE SLOW 75_OHM");
iomuxpad("pad_enet_td3", "enet1_rgmii_td3", "~LVTTL ~HYS ~PUE ~ODE MAX 40_OHM");
iomuxpad("pad_enet_td2", "enet1_rgmii_td2", "~LVTTL ~HYS ~PUE ~ODE MAX 40_OHM");
iomuxpad("pad_enet_td1", "enet1_rgmii_td1", "~LVTTL ~HYS ~PUE ~ODE MAX 40_OHM");
iomuxpad("pad_enet_td0", "enet1_rgmii_td0", "~LVTTL ~HYS ~PUE ~ODE MAX 40_OHM");
iomuxpad("pad_enet_tx_ctl", "enet1_rgmii_tx_ctl", "~LVTTL ~HYS ~PUE ~ODE MAX 40_OHM VSEL_0");
iomuxpad("pad_enet_txc", "enet1_rgmii_txc", "~LVTTL ~HYS ~PUE ~ODE MAX 40_OHM");
iomuxpad("pad_enet_rxc", "enet1_rgmii_rxc", "~LVTTL HYS ~PUE ~ODE FAST 255_OHM");
iomuxpad("pad_enet_rx_ctl", "enet1_rgmii_rx_ctl", "~LVTTL HYS ~PUE ~ODE FAST 255_OHM");
iomuxpad("pad_enet_rd0", "enet1_rgmii_rd0", "~LVTTL HYS ~PUE ~ODE FAST 255_OHM");
iomuxpad("pad_enet_rd1", "enet1_rgmii_rd1", "~LVTTL HYS ~PUE ~ODE FAST 255_OHM");
iomuxpad("pad_enet_rd2", "enet1_rgmii_rd2", "~LVTTL HYS ~PUE ~ODE FAST 255_OHM");
iomuxpad("pad_enet_rd3", "enet1_rgmii_rd3", "~LVTTL HYS ~PUE ~ODE FAST 255_OHM");
setclkgate("enet1.ipp_ind_mac0_txclk", 0);
setclkgate("sim_enet.mainclk", 0);
setclkrate("enet1.ipg_clk", "system_pll1_div3", Busclk);
setclkrate("enet1.ipp_ind_mac0_txclk", "system_pll2_div8", Txclk);
setclkrate("enet1.ipg_clk_time", "system_pll2_div10", Ptpclk);
setclkgate("enet1.ipp_ind_mac0_txclk", 1);
setclkgate("sim_enet.mainclk", 1);
if(reset(edev) < 0)
return -1;
intrenable(edev->irq+0, interrupt, edev, BUSUNKNOWN, edev->name);
intrenable(edev->irq+1, interrupt, edev, BUSUNKNOWN, edev->name);
intrenable(edev->irq+2, interrupt, edev, BUSUNKNOWN, edev->name);
intrenable(edev->irq+3, interrupt, edev, BUSUNKNOWN, edev->name);
return 0;
}
void
etherimxlink(void)
{
addethercard("imx", pnp);
}