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smc9000.c
#ifdef ALLMULTI #error multicast support is not yet implemented #endif /*------------------------------------------------------------------------ * smc9000.c * This is a Etherboot driver for SMC's 9000 series of Ethernet cards. * * Copyright (C) 1998 Daniel Engstrm <daniel.engstrom@riksnett.no> * Based on the Linux SMC9000 driver, smc9194.c by Eric Stahlman * Copyright (C) 1996 by Erik Stahlman <eric@vt.edu> * * This software may be used and distributed according to the terms * of the GNU Public License, incorporated herein by reference. * * "Features" of the SMC chip: * 4608 byte packet memory. ( for the 91C92/4. Others have more ) * EEPROM for configuration * AUI/TP selection * * Authors * Erik Stahlman <erik@vt.edu> * Daniel Engstrm <daniel.engstrom@riksnett.no> * * History * 98-09-25 Daniel Engstrm Etherboot driver crated from Eric's * Linux driver. * *---------------------------------------------------------------------------*/ FILE_LICENCE ( GPL_ANY ); #define LINUX_OUT_MACROS 1 #define SMC9000_DEBUG 0 #if SMC9000_DEBUG > 1 #define PRINTK2 printf #else #define PRINTK2(args...) #endif #include <gpxe/ethernet.h> #include <errno.h> #include "etherboot.h" #include "nic.h" #include <gpxe/isa.h> #include "smc9000.h" # define _outb outb # define _outw outw static const char smc9000_version[] = "Version 0.99 98-09-30"; static const char *interfaces[ 2 ] = { "TP", "AUI" }; static const char *chip_ids[ 15 ] = { NULL, NULL, NULL, /* 3 */ "SMC91C90/91C92", /* 4 */ "SMC91C94", /* 5 */ "SMC91C95", NULL, /* 7 */ "SMC91C100", /* 8 */ "SMC91C100FD", /* 9 */ "SMC91C11xFD", NULL, NULL, NULL, NULL, NULL }; static const char smc91c96_id[] = "SMC91C96"; /*------------------------------------------------------------ . Reads a register from the MII Management serial interface .-------------------------------------------------------------*/ static word smc_read_phy_register(int ioaddr, byte phyaddr, byte phyreg) { int oldBank; unsigned int i; byte mask; word mii_reg; byte bits[64]; int clk_idx = 0; int input_idx; word phydata; // 32 consecutive ones on MDO to establish sync for (i = 0; i < 32; ++i) bits[clk_idx++] = MII_MDOE | MII_MDO; // Start code <01> bits[clk_idx++] = MII_MDOE; bits[clk_idx++] = MII_MDOE | MII_MDO; // Read command <10> bits[clk_idx++] = MII_MDOE | MII_MDO; bits[clk_idx++] = MII_MDOE; // Output the PHY address, msb first mask = (byte)0x10; for (i = 0; i < 5; ++i) { if (phyaddr & mask) bits[clk_idx++] = MII_MDOE | MII_MDO; else bits[clk_idx++] = MII_MDOE; // Shift to next lowest bit mask >>= 1; } // Output the phy register number, msb first mask = (byte)0x10; for (i = 0; i < 5; ++i) { if (phyreg & mask) bits[clk_idx++] = MII_MDOE | MII_MDO; else bits[clk_idx++] = MII_MDOE; // Shift to next lowest bit mask >>= 1; } // Tristate and turnaround (2 bit times) bits[clk_idx++] = 0; //bits[clk_idx++] = 0; // Input starts at this bit time input_idx = clk_idx; // Will input 16 bits for (i = 0; i < 16; ++i) bits[clk_idx++] = 0; // Final clock bit bits[clk_idx++] = 0; // Save the current bank oldBank = inw( ioaddr+BANK_SELECT ); // Select bank 3 SMC_SELECT_BANK(ioaddr, 3); // Get the current MII register value mii_reg = inw( ioaddr+MII_REG ); // Turn off all MII Interface bits mii_reg &= ~(MII_MDOE|MII_MCLK|MII_MDI|MII_MDO); // Clock all 64 cycles for (i = 0; i < sizeof(bits); ++i) { // Clock Low - output data outw( mii_reg | bits[i], ioaddr+MII_REG ); udelay(50); // Clock Hi - input data outw( mii_reg | bits[i] | MII_MCLK, ioaddr+MII_REG ); udelay(50); bits[i] |= inw( ioaddr+MII_REG ) & MII_MDI; } // Return to idle state // Set clock to low, data to low, and output tristated outw( mii_reg, ioaddr+MII_REG ); udelay(50); // Restore original bank select SMC_SELECT_BANK(ioaddr, oldBank); // Recover input data phydata = 0; for (i = 0; i < 16; ++i) { phydata <<= 1; if (bits[input_idx++] & MII_MDI) phydata |= 0x0001; } #if (SMC_DEBUG > 2 ) printf("smc_read_phy_register(): phyaddr=%x,phyreg=%x,phydata=%x\n", phyaddr, phyreg, phydata); #endif return(phydata); } /*------------------------------------------------------------ . Writes a register to the MII Management serial interface .-------------------------------------------------------------*/ static void smc_write_phy_register(int ioaddr, byte phyaddr, byte phyreg, word phydata) { int oldBank; unsigned int i; word mask; word mii_reg; byte bits[65]; int clk_idx = 0; // 32 consecutive ones on MDO to establish sync for (i = 0; i < 32; ++i) bits[clk_idx++] = MII_MDOE | MII_MDO; // Start code <01> bits[clk_idx++] = MII_MDOE; bits[clk_idx++] = MII_MDOE | MII_MDO; // Write command <01> bits[clk_idx++] = MII_MDOE; bits[clk_idx++] = MII_MDOE | MII_MDO; // Output the PHY address, msb first mask = (byte)0x10; for (i = 0; i < 5; ++i) { if (phyaddr & mask) bits[clk_idx++] = MII_MDOE | MII_MDO; else bits[clk_idx++] = MII_MDOE; // Shift to next lowest bit mask >>= 1; } // Output the phy register number, msb first mask = (byte)0x10; for (i = 0; i < 5; ++i) { if (phyreg & mask) bits[clk_idx++] = MII_MDOE | MII_MDO; else bits[clk_idx++] = MII_MDOE; // Shift to next lowest bit mask >>= 1; } // Tristate and turnaround (2 bit times) bits[clk_idx++] = 0; bits[clk_idx++] = 0; // Write out 16 bits of data, msb first mask = 0x8000; for (i = 0; i < 16; ++i) { if (phydata & mask) bits[clk_idx++] = MII_MDOE | MII_MDO; else bits[clk_idx++] = MII_MDOE; // Shift to next lowest bit mask >>= 1; } // Final clock bit (tristate) bits[clk_idx++] = 0; // Save the current bank oldBank = inw( ioaddr+BANK_SELECT ); // Select bank 3 SMC_SELECT_BANK(ioaddr, 3); // Get the current MII register value mii_reg = inw( ioaddr+MII_REG ); // Turn off all MII Interface bits mii_reg &= ~(MII_MDOE|MII_MCLK|MII_MDI|MII_MDO); // Clock all cycles for (i = 0; i < sizeof(bits); ++i) { // Clock Low - output data outw( mii_reg | bits[i], ioaddr+MII_REG ); udelay(50); // Clock Hi - input data outw( mii_reg | bits[i] | MII_MCLK, ioaddr+MII_REG ); udelay(50); bits[i] |= inw( ioaddr+MII_REG ) & MII_MDI; } // Return to idle state // Set clock to low, data to low, and output tristated outw( mii_reg, ioaddr+MII_REG ); udelay(50); // Restore original bank select SMC_SELECT_BANK(ioaddr, oldBank); #if (SMC_DEBUG > 2 ) printf("smc_write_phy_register(): phyaddr=%x,phyreg=%x,phydata=%x\n", phyaddr, phyreg, phydata); #endif } /*------------------------------------------------------------ . Finds and reports the PHY address .-------------------------------------------------------------*/ static int smc_detect_phy(int ioaddr, byte *pphyaddr) { word phy_id1; word phy_id2; int phyaddr; int found = 0; // Scan all 32 PHY addresses if necessary for (phyaddr = 0; phyaddr < 32; ++phyaddr) { // Read the PHY identifiers phy_id1 = smc_read_phy_register(ioaddr, phyaddr, PHY_ID1_REG); phy_id2 = smc_read_phy_register(ioaddr, phyaddr, PHY_ID2_REG); // Make sure it is a valid identifier if ((phy_id2 > 0x0000) && (phy_id2 < 0xffff) && (phy_id1 > 0x0000) && (phy_id1 < 0xffff)) { if ((phy_id1 != 0x8000) && (phy_id2 != 0x8000)) { // Save the PHY's address *pphyaddr = phyaddr; found = 1; break; } } } if (!found) { printf("No PHY found\n"); return(0); } // Set the PHY type if ( (phy_id1 == 0x0016) && ((phy_id2 & 0xFFF0) == 0xF840 ) ) { printf("PHY=LAN83C183 (LAN91C111 Internal)\n"); } if ( (phy_id1 == 0x0282) && ((phy_id2 & 0xFFF0) == 0x1C50) ) { printf("PHY=LAN83C180\n"); } return(1); } /*------------------------------------------------------------ . Configures the specified PHY using Autonegotiation. Calls . smc_phy_fixed() if the user has requested a certain config. .-------------------------------------------------------------*/ static void smc_phy_configure(int ioaddr) { int timeout; byte phyaddr; word my_phy_caps; // My PHY capabilities word my_ad_caps; // My Advertised capabilities word status; int failed = 0; int rpc_cur_mode = RPC_DEFAULT; int lastPhy18; // Find the address and type of our phy if (!smc_detect_phy(ioaddr, &phyaddr)) { return; } // Reset the PHY, setting all other bits to zero smc_write_phy_register(ioaddr, phyaddr, PHY_CNTL_REG, PHY_CNTL_RST); // Wait for the reset to complete, or time out timeout = 6; // Wait up to 3 seconds while (timeout--) { if (!(smc_read_phy_register(ioaddr, phyaddr, PHY_CNTL_REG) & PHY_CNTL_RST)) { // reset complete break; } mdelay(500); // wait 500 millisecs } if (timeout < 1) { PRINTK2("PHY reset timed out\n"); return; } // Read PHY Register 18, Status Output lastPhy18 = smc_read_phy_register(ioaddr, phyaddr, PHY_INT_REG); // Enable PHY Interrupts (for register 18) // Interrupts listed here are disabled smc_write_phy_register(ioaddr, phyaddr, PHY_MASK_REG, PHY_INT_LOSSSYNC | PHY_INT_CWRD | PHY_INT_SSD | PHY_INT_ESD | PHY_INT_RPOL | PHY_INT_JAB | PHY_INT_SPDDET | PHY_INT_DPLXDET); /* Configure the Receive/Phy Control register */ SMC_SELECT_BANK(ioaddr, 0); outw( rpc_cur_mode, ioaddr + RPC_REG ); // Copy our capabilities from PHY_STAT_REG to PHY_AD_REG my_phy_caps = smc_read_phy_register(ioaddr, phyaddr, PHY_STAT_REG); my_ad_caps = PHY_AD_CSMA; // I am CSMA capable if (my_phy_caps & PHY_STAT_CAP_T4) my_ad_caps |= PHY_AD_T4; if (my_phy_caps & PHY_STAT_CAP_TXF) my_ad_caps |= PHY_AD_TX_FDX; if (my_phy_caps & PHY_STAT_CAP_TXH) my_ad_caps |= PHY_AD_TX_HDX; if (my_phy_caps & PHY_STAT_CAP_TF) my_ad_caps |= PHY_AD_10_FDX; if (my_phy_caps & PHY_STAT_CAP_TH) my_ad_caps |= PHY_AD_10_HDX; // Update our Auto-Neg Advertisement Register smc_write_phy_register(ioaddr, phyaddr, PHY_AD_REG, my_ad_caps); PRINTK2("phy caps=%x\n", my_phy_caps); PRINTK2("phy advertised caps=%x\n", my_ad_caps); // Restart auto-negotiation process in order to advertise my caps smc_write_phy_register( ioaddr, phyaddr, PHY_CNTL_REG, PHY_CNTL_ANEG_EN | PHY_CNTL_ANEG_RST ); // Wait for the auto-negotiation to complete. This may take from // 2 to 3 seconds. // Wait for the reset to complete, or time out timeout = 20; // Wait up to 10 seconds while (timeout--) { status = smc_read_phy_register(ioaddr, phyaddr, PHY_STAT_REG); if (status & PHY_STAT_ANEG_ACK) { // auto-negotiate complete break; } mdelay(500); // wait 500 millisecs // Restart auto-negotiation if remote fault if (status & PHY_STAT_REM_FLT) { PRINTK2("PHY remote fault detected\n"); // Restart auto-negotiation PRINTK2("PHY restarting auto-negotiation\n"); smc_write_phy_register( ioaddr, phyaddr, PHY_CNTL_REG, PHY_CNTL_ANEG_EN | PHY_CNTL_ANEG_RST | PHY_CNTL_SPEED | PHY_CNTL_DPLX); } } if (timeout < 1) { PRINTK2("PHY auto-negotiate timed out\n"); failed = 1; } // Fail if we detected an auto-negotiate remote fault if (status & PHY_STAT_REM_FLT) { PRINTK2("PHY remote fault detected\n"); failed = 1; } // Set our sysctl parameters to match auto-negotiation results if ( lastPhy18 & PHY_INT_SPDDET ) { PRINTK2("PHY 100BaseT\n"); rpc_cur_mode |= RPC_SPEED; } else { PRINTK2("PHY 10BaseT\n"); rpc_cur_mode &= ~RPC_SPEED; } if ( lastPhy18 & PHY_INT_DPLXDET ) { PRINTK2("PHY Full Duplex\n"); rpc_cur_mode |= RPC_DPLX; } else { PRINTK2("PHY Half Duplex\n"); rpc_cur_mode &= ~RPC_DPLX; } // Re-Configure the Receive/Phy Control register outw( rpc_cur_mode, ioaddr + RPC_REG ); } /* * Function: smc_reset( int ioaddr ) * Purpose: * This sets the SMC91xx chip to its normal state, hopefully from whatever * mess that any other DOS driver has put it in. * * Maybe I should reset more registers to defaults in here? SOFTRESET should * do that for me. * * Method: * 1. send a SOFT RESET * 2. wait for it to finish * 3. reset the memory management unit * 4. clear all interrupts * */ static void smc_reset(int ioaddr) { /* This resets the registers mostly to defaults, but doesn't * affect EEPROM. That seems unnecessary */ SMC_SELECT_BANK(ioaddr, 0); _outw( RCR_SOFTRESET, ioaddr + RCR ); /* this should pause enough for the chip to be happy */ SMC_DELAY(ioaddr); /* Set the transmit and receive configuration registers to * default values */ _outw(RCR_CLEAR, ioaddr + RCR); _outw(TCR_CLEAR, ioaddr + TCR); /* Reset the MMU */ SMC_SELECT_BANK(ioaddr, 2); _outw( MC_RESET, ioaddr + MMU_CMD ); /* Note: It doesn't seem that waiting for the MMU busy is needed here, * but this is a place where future chipsets _COULD_ break. Be wary * of issuing another MMU command right after this */ _outb(0, ioaddr + INT_MASK); } /*---------------------------------------------------------------------- * Function: smc9000_probe_addr( int ioaddr ) * * Purpose: * Tests to see if a given ioaddr points to an SMC9xxx chip. * Returns a 1 on success * * Algorithm: * (1) see if the high byte of BANK_SELECT is 0x33 * (2) compare the ioaddr with the base register's address * (3) see if I recognize the chip ID in the appropriate register * * --------------------------------------------------------------------- */ static int smc9000_probe_addr( isa_probe_addr_t ioaddr ) { word bank; word revision_register; word base_address_register; /* First, see if the high byte is 0x33 */ bank = inw(ioaddr + BANK_SELECT); if ((bank & 0xFF00) != 0x3300) { return 0; } /* The above MIGHT indicate a device, but I need to write to further * test this. */ _outw(0x0, ioaddr + BANK_SELECT); bank = inw(ioaddr + BANK_SELECT); if ((bank & 0xFF00) != 0x3300) { return 0; } /* well, we've already written once, so hopefully another time won't * hurt. This time, I need to switch the bank register to bank 1, * so I can access the base address register */ SMC_SELECT_BANK(ioaddr, 1); base_address_register = inw(ioaddr + BASE); if (ioaddr != (base_address_register >> 3 & 0x3E0)) { DBG("SMC9000: IOADDR %hX doesn't match configuration (%hX)." "Probably not a SMC chip\n", ioaddr, base_address_register >> 3 & 0x3E0); /* well, the base address register didn't match. Must not have * been a SMC chip after all. */ return 0; } /* check if the revision register is something that I recognize. * These might need to be added to later, as future revisions * could be added. */ SMC_SELECT_BANK(ioaddr, 3); revision_register = inw(ioaddr + REVISION); if (!chip_ids[(revision_register >> 4) & 0xF]) { /* I don't recognize this chip, so... */ DBG( "SMC9000: IO %hX: Unrecognized revision register:" " %hX, Contact author.\n", ioaddr, revision_register ); return 0; } /* at this point I'll assume that the chip is an SMC9xxx. * It might be prudent to check a listing of MAC addresses * against the hardware address, or do some other tests. */ return 1; } /************************************************************************** * ETH_TRANSMIT - Transmit a frame ***************************************************************************/ static void smc9000_transmit( struct nic *nic, const char *d, /* Destination */ unsigned int t, /* Type */ unsigned int s, /* size */ const char *p) /* Packet */ { word length; /* real, length incl. header */ word numPages; unsigned long time_out; byte packet_no; word status; int i; /* We dont pad here since we can have the hardware doing it for us */ length = (s + ETH_HLEN + 1)&~1; /* convert to MMU pages */ numPages = length / 256; if (numPages > 7 ) { DBG("SMC9000: Far too big packet error. \n"); return; } /* dont try more than, say 30 times */ for (i=0;i<30;i++) { /* now, try to allocate the memory */ SMC_SELECT_BANK(nic->ioaddr, 2); _outw(MC_ALLOC | numPages, nic->ioaddr + MMU_CMD); status = 0; /* wait for the memory allocation to finnish */ for (time_out = currticks() + 5*TICKS_PER_SEC; currticks() < time_out; ) { status = inb(nic->ioaddr + INTERRUPT); if ( status & IM_ALLOC_INT ) { /* acknowledge the interrupt */ _outb(IM_ALLOC_INT, nic->ioaddr + INTERRUPT); break; } } if ((status & IM_ALLOC_INT) != 0 ) { /* We've got the memory */ break; } else { printf("SMC9000: Memory allocation timed out, resetting MMU.\n"); _outw(MC_RESET, nic->ioaddr + MMU_CMD); } } /* If I get here, I _know_ there is a packet slot waiting for me */ packet_no = inb(nic->ioaddr + PNR_ARR + 1); if (packet_no & 0x80) { /* or isn't there? BAD CHIP! */ printf("SMC9000: Memory allocation failed. \n"); return; } /* we have a packet address, so tell the card to use it */ _outb(packet_no, nic->ioaddr + PNR_ARR); /* point to the beginning of the packet */ _outw(PTR_AUTOINC, nic->ioaddr + POINTER); #if SMC9000_DEBUG > 2 printf("Trying to xmit packet of length %hX\n", length ); #endif /* send the packet length ( +6 for status, length and ctl byte ) * and the status word ( set to zeros ) */ _outw(0, nic->ioaddr + DATA_1 ); /* send the packet length ( +6 for status words, length, and ctl) */ _outb((length+6) & 0xFF, nic->ioaddr + DATA_1); _outb((length+6) >> 8 , nic->ioaddr + DATA_1); /* Write the contents of the packet */ /* The ethernet header first... */ outsw(nic->ioaddr + DATA_1, d, ETH_ALEN >> 1); outsw(nic->ioaddr + DATA_1, nic->node_addr, ETH_ALEN >> 1); _outw(htons(t), nic->ioaddr + DATA_1); /* ... the data ... */ outsw(nic->ioaddr + DATA_1 , p, s >> 1); /* ... and the last byte, if there is one. */ if ((s & 1) == 0) { _outw(0, nic->ioaddr + DATA_1); } else { _outb(p[s-1], nic->ioaddr + DATA_1); _outb(0x20, nic->ioaddr + DATA_1); } /* and let the chipset deal with it */ _outw(MC_ENQUEUE , nic->ioaddr + MMU_CMD); status = 0; time_out = currticks() + 5*TICKS_PER_SEC; do { status = inb(nic->ioaddr + INTERRUPT); if ((status & IM_TX_INT ) != 0) { word tx_status; /* ack interrupt */ _outb(IM_TX_INT, nic->ioaddr + INTERRUPT); packet_no = inw(nic->ioaddr + FIFO_PORTS); packet_no &= 0x7F; /* select this as the packet to read from */ _outb( packet_no, nic->ioaddr + PNR_ARR ); /* read the first word from this packet */ _outw( PTR_AUTOINC | PTR_READ, nic->ioaddr + POINTER ); tx_status = inw( nic->ioaddr + DATA_1 ); if (0 == (tx_status & TS_SUCCESS)) { DBG("SMC9000: TX FAIL STATUS: %hX \n", tx_status); /* re-enable transmit */ SMC_SELECT_BANK(nic->ioaddr, 0); _outw(inw(nic->ioaddr + TCR ) | TCR_ENABLE, nic->ioaddr + TCR ); } /* kill the packet */ SMC_SELECT_BANK(nic->ioaddr, 2); _outw(MC_FREEPKT, nic->ioaddr + MMU_CMD); return; } }while(currticks() < time_out); printf("SMC9000: TX timed out, resetting board\n"); smc_reset(nic->ioaddr); return; } /************************************************************************** * ETH_POLL - Wait for a frame ***************************************************************************/ static int smc9000_poll(struct nic *nic, int retrieve) { SMC_SELECT_BANK(nic->ioaddr, 2); if (inw(nic->ioaddr + FIFO_PORTS) & FP_RXEMPTY) return 0; if ( ! retrieve ) return 1; /* start reading from the start of the packet */ _outw(PTR_READ | PTR_RCV | PTR_AUTOINC, nic->ioaddr + POINTER); /* First read the status and check that we're ok */ if (!(inw(nic->ioaddr + DATA_1) & RS_ERRORS)) { /* Next: read the packet length and mask off the top bits */ nic->packetlen = (inw(nic->ioaddr + DATA_1) & 0x07ff); /* the packet length includes the 3 extra words */ nic->packetlen -= 6; #if SMC9000_DEBUG > 2 printf(" Reading %d words (and %d byte(s))\n", (nic->packetlen >> 1), nic->packetlen & 1); #endif /* read the packet (and the last "extra" word) */ insw(nic->ioaddr + DATA_1, nic->packet, (nic->packetlen+2) >> 1); /* is there an odd last byte ? */ if (nic->packet[nic->packetlen+1] & 0x20) nic->packetlen++; /* error or good, tell the card to get rid of this packet */ _outw(MC_RELEASE, nic->ioaddr + MMU_CMD); return 1; } printf("SMC9000: RX error\n"); /* error or good, tell the card to get rid of this packet */ _outw(MC_RELEASE, nic->ioaddr + MMU_CMD); return 0; } static void smc9000_disable ( struct nic *nic, struct isa_device *isa __unused ) { smc_reset(nic->ioaddr); /* no more interrupts for me */ SMC_SELECT_BANK(nic->ioaddr, 2); _outb( 0, nic->ioaddr + INT_MASK); /* and tell the card to stay away from that nasty outside world */ SMC_SELECT_BANK(nic->ioaddr, 0); _outb( RCR_CLEAR, nic->ioaddr + RCR ); _outb( TCR_CLEAR, nic->ioaddr + TCR ); } static void smc9000_irq(struct nic *nic __unused, irq_action_t action __unused) { switch ( action ) { case DISABLE : break; case ENABLE : break; case FORCE : break; } } static struct nic_operations smc9000_operations = { .connect = dummy_connect, .poll = smc9000_poll, .transmit = smc9000_transmit, .irq = smc9000_irq, }; /************************************************************************** * ETH_PROBE - Look for an adapter ***************************************************************************/ static int smc9000_probe ( struct nic *nic, struct isa_device *isa ) { unsigned short revision; int memory; int media; const char * version_string; const char * if_string; int i; nic->irqno = 0; nic->ioaddr = isa->ioaddr; /* * Get the MAC address ( bank 1, regs 4 - 9 ) */ SMC_SELECT_BANK(nic->ioaddr, 1); for ( i = 0; i < 6; i += 2 ) { word address; address = inw(nic->ioaddr + ADDR0 + i); nic->node_addr[i+1] = address >> 8; nic->node_addr[i] = address & 0xFF; } /* get the memory information */ SMC_SELECT_BANK(nic->ioaddr, 0); memory = ( inw(nic->ioaddr + MCR) >> 9 ) & 0x7; /* multiplier */ memory *= 256 * (inw(nic->ioaddr + MIR) & 0xFF); /* * Now, I want to find out more about the chip. This is sort of * redundant, but it's cleaner to have it in both, rather than having * one VERY long probe procedure. */ SMC_SELECT_BANK(nic->ioaddr, 3); revision = inw(nic->ioaddr + REVISION); version_string = chip_ids[(revision >> 4) & 0xF]; if (((revision & 0xF0) >> 4 == CHIP_9196) && ((revision & 0x0F) >= REV_9196)) { /* This is a 91c96. 'c96 has the same chip id as 'c94 (4) but * a revision starting at 6 */ version_string = smc91c96_id; } if ( !version_string ) { /* I shouldn't get here because this call was done before.... */ return 0; } /* is it using AUI or 10BaseT ? */ SMC_SELECT_BANK(nic->ioaddr, 1); if (inw(nic->ioaddr + CONFIG) & CFG_AUI_SELECT) media = 2; else media = 1; if_string = interfaces[media - 1]; /* now, reset the chip, and put it into a known state */ smc_reset(nic->ioaddr); printf("SMC9000 %s\n", smc9000_version); DBG("Copyright (C) 1998 Daniel Engstr\x94m\n"); DBG("Copyright (C) 1996 Eric Stahlman\n"); printf("%s rev:%d I/O port:%hX Interface:%s RAM:%d bytes \n", version_string, revision & 0xF, nic->ioaddr, if_string, memory ); DBG ( "Ethernet MAC address: %s\n", eth_ntoa ( nic->node_addr ) ); SMC_SELECT_BANK(nic->ioaddr, 0); /* see the header file for options in TCR/RCR NORMAL*/ _outw(TCR_NORMAL, nic->ioaddr + TCR); _outw(RCR_NORMAL, nic->ioaddr + RCR); /* Select which interface to use */ SMC_SELECT_BANK(nic->ioaddr, 1); if ( media == 1 ) { _outw( inw( nic->ioaddr + CONFIG ) & ~CFG_AUI_SELECT, nic->ioaddr + CONFIG ); } else if ( media == 2 ) { _outw( inw( nic->ioaddr + CONFIG ) | CFG_AUI_SELECT, nic->ioaddr + CONFIG ); } smc_phy_configure(nic->ioaddr); nic->nic_op = &smc9000_operations; return 1; } /* * The SMC9000 can be at any of the following port addresses. To * change for a slightly different card, you can add it to the array. * */ static isa_probe_addr_t smc9000_probe_addrs[] = { 0x200, 0x220, 0x240, 0x260, 0x280, 0x2A0, 0x2C0, 0x2E0, 0x300, 0x320, 0x340, 0x360, 0x380, 0x3A0, 0x3C0, 0x3E0, }; ISA_DRIVER ( smc9000_driver, smc9000_probe_addrs, smc9000_probe_addr, GENERIC_ISAPNP_VENDOR, 0x8228 ); DRIVER ( "SMC9000", nic_driver, isa_driver, smc9000_driver, smc9000_probe, smc9000_disable ); ISA_ROM ( "smc9000", "SMC9000" ); /* * Local variables: * c-basic-offset: 8 * c-indent-level: 8 * tab-width: 8 * End: */
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