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//============================================================================= // // ether_test.c - Cyclone Diagnostics // //============================================================================= //####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc. // // eCos 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 or (at your option) any later version. // // eCos 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 eCos; if not, write to the Free Software Foundation, Inc., // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. // // As a special exception, if other files instantiate templates or use macros // or inline functions from this file, or you compile this file and link it // with other works to produce a work based on this file, this file does not // by itself cause the resulting work to be covered by the GNU General Public // License. However the source code for this file must still be made available // in accordance with section (3) of the GNU General Public License. // // This exception does not invalidate any other reasons why a work based on // this file might be covered by the GNU General Public License. // // Alternative licenses for eCos may be arranged by contacting Red Hat, Inc. // at http://sources.redhat.com/ecos/ecos-license/ // ------------------------------------------- //####ECOSGPLCOPYRIGHTEND#### //============================================================================= //#####DESCRIPTIONBEGIN#### // // Author(s): Scott Coulter, Jeff Frazier, Eric Breeden // Contributors: // Date: 2001-01-25 // Purpose: // Description: // //####DESCRIPTIONEND#### // //===========================================================================*/ #include <redboot.h> #include <cyg/io/pci_hw.h> #include <cyg/io/pci.h> #include "pci_bios.h" #include "iq80310.h" #include "ether_test.h" /* Forward declarations */ static int i557SelfTest (void); static int i557Init (void); static int i557Config (UINT8 loopBackMode); static int i557AddrSet (void); static int i557RUStart (void); static void setUpPacket (char *p); static int txPacket (char *p); static char *malloc (int n); static int waitForRxInt(void); static int get_ether_addr(int unit, UINT8 *buf, int print_flag); /* Externals */ extern long decIn(void); extern void sgets(char *s); extern int enable_external_interrupt (int int_id); extern int isr_connect(int int_num, void (*handler)(int), int arg); extern STATUS pci_isr_connect (int intline, int bus, int device, int (*handler)(int), int arg); extern void delay_ms(int msecs); extern int eeprom_read (UINT32 pci_base,/* PCI Base address */ int eeprom_addr, /* word offset from start of eeprom */ UINT16 *p_data,/* where to put data in memory */ int nwords /* number of 16bit words to read */ ); extern int eeprom_write (UINT32 pci_base,/* PCI Base address */ int eeprom_addr, /* word offset from start of eeprom */ UINT16 *p_data,/* data location in memory */ int nwords /* number of 16bit words to write */ ); /* Globals needed by both main program and irq handler */ static volatile struct SCBtype *pSCB; /* Pointer to SCB in use */ static volatile UINT32 waitSem; /* Used to block test until interrupt */ static volatile UINT32 rxSem; /* Used to block test until rx sinterrupt */ static UINT16 i557Status; /* Status code from SCB */ static volatile char *mem_pool; /* Ptr to malloc's free memory pool */ static UINT32 adapter[2]; /* Ptr to PCI Ethernet adapter */ static UINT8 node_address[6]; /*static long timer0_ticks = 0;*/ static char buf[4]; static int count = 0; static int forever_flag = FALSE; static UINT32 phy_id = 0; /* 82557 required data structures which must be allocated */ static struct rfd *pRfd; static union cmdBlock *pCmdBlock; static char *pPacketBuf; #define SPEED_NOLINK 0 #define SPEED_10M 10 #define SPEED_100M 100 static int link_speed = SPEED_NOLINK; UINT8 unit_intpin; int unit_devno, unit_busno, unit_funcno; #define BUSY_WAIT_LIMIT 0xf000 /* the upper limit on a busy wait for command completion, etc. */ static void mask_557_ints (void) { pSCB->cmdStat.bits.m = 1; } static void unmask_557_ints (void) { pSCB->cmdStat.bits.m = 0; } /***************************************************************************** * pci_ether_test - i8255x PCI Ethernet test * * Main diagnostic routine for the Intel 8255x 10/100BaseT Ethernet Controller * family. Arguments include the PCI bus, device and function numbers of the * controller that is to be tested. * */ void pci_ether_test (UINT32 busno, UINT32 devno, UINT32 funcno) { volatile int i; int ntimes; int broadcom_flag = FALSE; UINT16 phy_addr_reg, temp1, temp2; cyg_pci_device_id devid; count = 0; devid = CYG_PCI_DEV_MAKE_ID(busno, CYG_PCI_DEV_MAKE_DEVFN(devno,funcno)); /* read the PCI BAR for the Ethernet controller */ cyg_pci_read_config_uint32(devid, 0x10, &adapter[0]); /* strip off BAR indicator bits */ adapter[0] &= 0xfffffff0; unit_devno = devno; unit_busno = busno; unit_funcno = funcno; /* pointer to on-chip SCB */ pSCB = (struct SCBtype *)(adapter[0] + SCB_OFFSET); unit_intpin = INTA; printf ("PCI Base Address = 0x%X\n", adapter[0]); printf ("PCI Interrupt Pin = 0x%02X\n", unit_intpin); /* Initialize malloc's memory pool pointer */ mem_pool = (char *) ETHER_MEM_POOL; /* Start the timer for delay implementation printf("Starting timer... "); StartTimer(); */ printf("Done.\n Resetting chip... "); /* reset the 82557 to start with a clean slate */ resetChip(); printf("Done.\n"); /* Get the UUT's ethernet address */ if (get_ether_addr (0, node_address, TRUE) == ERROR) { printf("Error Reading Adapter Ethernet Address\n"); return; } temp1 = readMDI(0, MDI_DEFAULT_PHY_ADDR, MDI_PHY_ID_1); temp2 = readMDI(0, MDI_DEFAULT_PHY_ADDR, MDI_PHY_ID_2); phy_id = ((temp1 << 16) | temp2); if ((phy_id & 0xfffffff0) == I82555_PHY_ID) { printf ("Intel 82555/558 PHY detected...\n"); /* dummy read for reliable status */ (void)readMDI (0, MDI_DEFAULT_PHY_ADDR, MDI_PHY_STAT); temp1 = readMDI (0, MDI_DEFAULT_PHY_ADDR, MDI_PHY_STAT); printf ("Status Register Link Status is %s\n", (temp1 & MDI_STAT_LINK) ? "UP" : "DOWN"); phy_addr_reg = readMDI (0, MDI_DEFAULT_PHY_ADDR, I82555_STATCTRL_REG); if (temp1 & MDI_STAT_LINK) { /* speed only valid with good LNK */ printf ("Connect Speed is %s\n", (phy_addr_reg & I82555_100_MBPS) ? "100Mbps" : "10Mbps"); link_speed = (phy_addr_reg & I82555_100_MBPS) ? SPEED_100M : SPEED_10M; } else printf ("Connect Speed is NOT VALID\n"); } if ((phy_id & 0xfffffff0) == ICS1890_PHY_ID) { printf ("Integrated Circuit Systems ICS1890 PHY detected...\n"); printf ("Revision = %c\n", 'A' + (phy_id & REVISION_MASK)); /* dummy read for reliable status */ (void)readMDI (0, MDI_DEFAULT_PHY_ADDR, ICS1890_QUICKPOLL_REG); temp1 = readMDI (0, MDI_DEFAULT_PHY_ADDR, ICS1890_QUICKPOLL_REG); printf ("Status Register Link Status is %s\n", (temp1 & QUICK_LINK_VALID) ? "UP" : "DOWN"); if (temp1 & QUICK_LINK_VALID) { /* speed only valid with good LNK */ printf ("Connect Speed is %s\n", (temp1 & QUICK_100_MBPS) ? "100Mbps" : "10Mbps"); link_speed = (temp1 & QUICK_100_MBPS) ? SPEED_100M : SPEED_10M; } else printf ("Connect Speed is NOT VALID\n"); } if ((phy_id & 0xfffffff0) == DP83840_PHY_ID) { printf ("National DP83840 PHY detected...\n"); printf ("Revision = %c\n", 'A' + (phy_id & REVISION_MASK)); /* dummy read for reliable status */ (void)readMDI (0, MDI_DEFAULT_PHY_ADDR, MDI_PHY_STAT); temp1 = readMDI (0, MDI_DEFAULT_PHY_ADDR, MDI_PHY_STAT); printf ("Status Register Link Status is %s\n", (temp1 & MDI_STAT_LINK) ? "UP" : "DOWN"); phy_addr_reg = readMDI (0 ,MDI_DEFAULT_PHY_ADDR, DP83840_PHY_ADDR_REG); if (temp1 & MDI_STAT_LINK) { /* speed only valid with good LNK */ printf ("Connect Speed is %s\n", (phy_addr_reg & PHY_ADDR_SPEED_10_MBPS) ? "10Mbps" : "100Mbps"); link_speed = (phy_addr_reg & PHY_ADDR_SPEED_10_MBPS) ? SPEED_10M : SPEED_100M; } else printf ("Connect Speed is NOT VALID\n"); } if ((phy_id & 0xfffffff0) == I82553_PHY_ID) { printf ("Intel 82553 PHY detected...\n"); printf ("Revision = %c\n", 'A' + (phy_id & REVISION_MASK)); broadcom_flag = TRUE; } if (phy_id == I82553_REVAB_PHY_ID) { printf ("Intel 82553 PHY detected...\n"); printf ("Revision = B\n"); broadcom_flag = TRUE; } if (broadcom_flag == TRUE) { temp2 = readMDI (0,MDI_DEFAULT_PHY_ADDR, I82553_PHY_EXT_REG0); printf ("Stepping = %02X\n", GET_REV_CNTR(temp2)); /* dummy read for reliable status */ (void)readMDI (0 ,MDI_DEFAULT_PHY_ADDR, MDI_PHY_STAT); temp1 = readMDI (0 ,MDI_DEFAULT_PHY_ADDR, MDI_PHY_STAT); printf ("Status Register Link Status is %s\n", (temp1 & MDI_STAT_LINK) ? "UP" : "DOWN"); if (temp1 & MDI_STAT_LINK) { /* speed only valid with good LNK */ printf ("Connect Speed is %s\n", (temp2 & EXT_REG0_100_MBPS) ? "100Mbps" : "10Mbps"); link_speed = (temp2 & EXT_REG0_100_MBPS) ? SPEED_100M : SPEED_10M; } else printf ("Connect Speed is NOT VALID\n"); } printf ("\n"); /* Run the built-in self test through the port register */ if (i557SelfTest () == ERROR) { mask_557_ints (); /* Disable 557 interrupt */ return; } /* Reset clears the interrupt mask */ mask_557_ints(); printf ("Press return to initialize ethernet controller.\n"); sgets (buf); /* Initialize data structures */ if (i557Init () == ERROR) { mask_557_ints (); /* Disable 557 interrupt */ return; } /* Set hardware address */ if (i557AddrSet () == ERROR) { mask_557_ints (); /* Disable 557 interrupt */ return; } printf ("Press return to perform internal loopback test.\n"); sgets (buf); /* Configure for internal loopback */ if (i557Config (INT_LOOP_BACK) == ERROR) { mask_557_ints (); /* Disable 557 interrupt */ return; } delay_ms(100); /* Initialize receive buffer and enable receiver */ if (i557RUStart () == ERROR) { mask_557_ints (); /* Disable 557 interrupt */ return; } /* Send a packet */ setUpPacket (pPacketBuf); if (txPacket (pPacketBuf) == ERROR) { mask_557_ints (); /* Disable 557 interrupt */ return; } printf ("Press return to perform loopback through PHY.\n"); sgets (buf); /* Configure for external loopback */ if (i557Config (EXT_LOOP_BACK) == ERROR) { mask_557_ints (); /* Disable 557 interrupt */ return; } delay_ms(100); /* Initialize receive buffer and enable receiver */ if (i557RUStart () == ERROR) { mask_557_ints (); /* Disable 557 interrupt */ return; } /* Send a packet */ setUpPacket (pPacketBuf); if (txPacket (pPacketBuf) == ERROR) { mask_557_ints (); /* Disable 557 interrupt */ return; } printf ("Press return to perform external loopback through\n"); printf ("10/100 Base T Hub. NOTE: If test duration is not forever,\n"); printf ("this test will work only if a properly functioning Hub\n"); printf ("and Twisted Pair cable are attached to the network connector\n"); printf ("on the front panel.\n"); sgets (buf); printf ("Enter the number of times to run test (0 = forever): "); ntimes = decIn(); printf ("\n\n"); if (i557RUStart () == ERROR) { mask_557_ints (); /* Disable 557 interrupt */ return; } setUpPacket (pPacketBuf); if (ntimes == 0) { forever_flag = TRUE; while (1) { if ((i557RUStart() == ERROR)||(txPacket (pPacketBuf) == ERROR)) { printf ("Double-check TP cable and 10/100 Base T Hub\n"); printf ("Try testing them with another system\n"); printf ("(such as a workstation) that is working correctly.\n"); mask_557_ints (); /* Disable 557 interrupt */ return; } count++; if (((count) % 1000) == 0) printf("Loopback Cycle Count = %d\n", count); } } else { forever_flag = FALSE; for (i=0; i<ntimes; i++) { if ((i557RUStart() == ERROR)||(txPacket (pPacketBuf) == ERROR)) { printf ("Double-check TP cable and 10/100 Base T Hub\n"); printf ("Try testing them with another system\n"); printf ("(such as a workstation) that is working correctly.\n"); mask_557_ints (); /* Disable 557 interrupt */ return; } count++; printf("Loopback Cycle Count = %d\n", count); } /* It worked! */ mask_557_ints (); /* Disable 557 interrupt */ printf ("\nEthernet controller passed. Press return to continue.\n"); sgets (buf); } } /* Perform internal self test - returns OK if sucessful, ERROR if not. */ static int i557SelfTest () { volatile struct selfTest *pSelfTestMem; UINT32 oldWord2; long delay; UINT32 temp; int rtnVal; /* reset the 82557 to start with a clean slate */ resetChip(); /* Allocate some memory for the self test */ pSelfTestMem = (struct selfTest *) malloc (sizeof(struct selfTest)); if (pSelfTestMem == NULL) { printf ("Couldn't get memory for self test.\n"); return (ERROR); } printf ("Sending PORT* self-test command...\n"); printf ("Local Dump address = 0x%X\n", pSelfTestMem); /* Set all bits in second word, wait until it changes or a timeout */ pSelfTestMem->u.word2 = ~0; oldWord2 = pSelfTestMem->u.word2; temp = ((UINT32) pSelfTestMem) + PORT_SELF_TEST; portWrite (temp); /* Wait for test completion or for timeout */ for (delay = 0; (delay < MAX_DELAY) && (pSelfTestMem->u.word2 == oldWord2); delay++) ; /* Wait... */ /* Print results */ printf ("Self test result: %s\n", (pSelfTestMem->u.bits.selfTest) ? "Fail" : "Pass"); printf ("ROM content test: %s\n", (pSelfTestMem->u.bits.romTest) ? "Fail" : "Pass"); printf ("Register test: %s\n", (pSelfTestMem->u.bits.regTest) ? "Fail" : "Pass"); printf ("Diagnose test: %s\n", (pSelfTestMem->u.bits.diagnTest) ? "Fail" : "Pass"); printf ("ROM signature: 0x%X\n", pSelfTestMem->romSig); rtnVal = pSelfTestMem->u.bits.selfTest ? ERROR : OK; return (rtnVal); } /* Initialize the 82557. */ static int i557Init (void) { /* Get memory for system data structures */ if ( ((pRfd = (struct rfd *) malloc (sizeof(struct rfd))) == NULL) || ((pPacketBuf = malloc(ETHERMTU + sizeof(UINT16) + 6)) == NULL) || ((pCmdBlock = (union cmdBlock *) malloc (sizeof(union cmdBlock))) == NULL) ) { printf ("Memory allocation failed.\n"); return (ERROR); } /* Set EL bits in command block and rfd so we don't fall of the end */ pCmdBlock->nop.el = END_OF_LIST; pRfd->el = END_OF_LIST; /* Reset chip and initialize */ printf ("Initializing... "); /* Reset 82557 */ resetChip (); /* set up the CU and RU base values to 0x0 */ sendCommand (LOAD_CU_BASE, RU_NOP, 0); sendCommand (CU_NOP, LOAD_RU_BASE, 0); /* Initialize interrupts */ /* if it is the onboard i82559, it does not use the conventional PCI interrupt routines because the interrupt is not multiplexed onto the PCI bus */ if ((unit_busno == 2) && (unit_devno == 0) && (unit_funcno == 0)) { if (isr_connect (ENET_INT_ID, (VOIDFUNCPTR)i557IntHandler, 0xdeadbeef) != OK) { printf ("Error connecting Ethernet interrupt!\n"); return (ERROR); } if (enable_external_interrupt (ENET_INT_ID) != OK) { printf ("Error enabling Ethernet interrupt!\n"); return (ERROR); } } else { /* use regular PCI int connect scheme */ if (pci_isr_connect (unit_intpin, unit_busno, unit_devno, i557IntHandler, 0xdeadbeef) != OK) { printf ("Error connecting Ethernet interrupt!\n"); return (ERROR); } } unmask_557_ints(); printf ("Done\n"); return (OK); } static int initPHY (UINT32 device_type, int loop_mode) { UINT16 temp_reg; UINT8 revision; /* strip off revision and phy. id information */ revision = (UINT8)(device_type & REVISION_MASK); device_type &= ~REVISION_MASK; switch (device_type) { case ICS1890_PHY_ID: temp_reg = readMDI (0, MDI_DEFAULT_PHY_ADDR, MDI_PHY_CTRL); /* get ready for loopback setting */ switch (loop_mode) { case EXT_LOOP_BACK: /* loopback on the MII interface */ temp_reg |= MDI_CTRL_LOOPBACK; /* MII loopback */ break; case INT_LOOP_BACK: default: break; } writeMDI(0, MDI_DEFAULT_PHY_ADDR, MDI_PHY_CTRL, temp_reg); break; case DP83840_PHY_ID: /* set the Intel-specified "must set" bits */ temp_reg = readMDI (0,MDI_DEFAULT_PHY_ADDR, DP83840_PCR_REG); temp_reg |= (PCR_TXREADY_SEL | PCR_FCONNECT); writeMDI (0,MDI_DEFAULT_PHY_ADDR, DP83840_PCR_REG, temp_reg); /* get ready for loopback setting */ temp_reg = readMDI (0,MDI_DEFAULT_PHY_ADDR, DP83840_LOOPBACK_REG); temp_reg &= CLEAR_LOOP_BITS; switch (loop_mode) { case EXT_LOOP_BACK: temp_reg |= TWISTER_LOOPBACK; break; case INT_LOOP_BACK: default: break; } writeMDI (0,MDI_DEFAULT_PHY_ADDR, DP83840_LOOPBACK_REG, temp_reg); break; case I82553_PHY_ID: case I82553_REVAB_PHY_ID: case I82555_PHY_ID: break; default: return (ERROR); break; } return (OK); } /* Set hardware address of the 82557. */ static int i557AddrSet () { printf ("Setting hardware ethernet address to "); printf ("%02X:%02X:%02X:", node_address[0], node_address[1], node_address[2]); printf ("%02X:%02X:%02X... ", node_address[3], node_address[4], node_address[5]); /* Set up iaSetup command block and execute */ memset((char *) pCmdBlock, 0, sizeof(union cmdBlock)); pCmdBlock->iaSetup.code = IA_SETUP; pCmdBlock->iaSetup.el = END_OF_LIST; memcpy(pCmdBlock->iaSetup.enetAddr, node_address, sizeof(node_address)); sendCommand (CU_START, RU_NOP, ((UINT32)pCmdBlock)); if ((waitForInt() == ERROR) || (pCmdBlock->iaSetup.ok != 1)) { printf ("failed. Status: 0x%04X.\n", pSCB->cmdStat.words.status); printf ("C bit = %d\n",pCmdBlock->iaSetup.c); printf ("OK bit = %d\n",pCmdBlock->iaSetup.ok); return (ERROR); } printf ("done.\n"); return (OK); } /* Configure the 82557. */ static int i557Config (UINT8 loopBackMode) /* None, int, or ext 1, 2 (see etherTest.h) */ { printf ("\nConfiguring for "); switch (loopBackMode) { case INT_LOOP_BACK: printf ("internal loopback... "); break; case EXT_LOOP_BACK: printf ("external loopback, LPBK* active... "); break; default: printf ("Unknown loopback mode, exiting...\n"); return (ERROR); } /* Set up configure command block and execute */ memset ((char *) pCmdBlock, 0, sizeof(union cmdBlock)); pCmdBlock->configure.code = CONFIGURE; pCmdBlock->configure.el = END_OF_LIST; pCmdBlock->configure.configData[ 0] = CONFIG_BYTE_00; pCmdBlock->configure.configData[ 1] = CONFIG_BYTE_01; pCmdBlock->configure.configData[ 2] = CONFIG_BYTE_02; pCmdBlock->configure.configData[ 3] = CONFIG_BYTE_03; pCmdBlock->configure.configData[ 4] = CONFIG_BYTE_04; pCmdBlock->configure.configData[ 5] = CONFIG_BYTE_05; pCmdBlock->configure.configData[ 6] = CONFIG_BYTE_06; pCmdBlock->configure.configData[ 7] = CONFIG_BYTE_07; pCmdBlock->configure.configData[ 8] = CONFIG_BYTE_08; pCmdBlock->configure.configData[ 9] = CONFIG_BYTE_09; pCmdBlock->configure.configData[10] = CONFIG_BYTE_10 | loopBackMode; pCmdBlock->configure.configData[11] = CONFIG_BYTE_11; pCmdBlock->configure.configData[12] = CONFIG_BYTE_12; pCmdBlock->configure.configData[13] = CONFIG_BYTE_13; pCmdBlock->configure.configData[14] = CONFIG_BYTE_14; pCmdBlock->configure.configData[15] = CONFIG_BYTE_15; pCmdBlock->configure.configData[16] = CONFIG_BYTE_16; pCmdBlock->configure.configData[17] = CONFIG_BYTE_17; pCmdBlock->configure.configData[18] = CONFIG_BYTE_18; if (link_speed == SPEED_100M) pCmdBlock->configure.configData[19] = CONFIG_BYTE_19_100T; else { pCmdBlock->configure.configData[19] = CONFIG_BYTE_19_10T; pCmdBlock->configure.configData[20] = CONFIG_BYTE_20; pCmdBlock->configure.configData[21] = CONFIG_BYTE_21; } sendCommand (CU_START, RU_NOP, ((UINT32)pCmdBlock)); if ((waitForInt() == ERROR) || (pCmdBlock->configure.ok != 1)) { printf ("failed. Status: 0x%04X.\n", pSCB->cmdStat.words.status); return (ERROR); } initPHY (phy_id, loopBackMode); /* set up the PHY interface appropriately */ printf ("done.\n"); return (OK); } static int i557RUStart (void) { volatile long delay; memset((char *) pRfd, 0, sizeof(struct rfd)); /* Set end-of-list bit in the rfd so we don't fall off the end */ pRfd->el = END_OF_LIST; pRfd->s = 1; pRfd->sf = 0; /* Simplified mode */ pRfd->rbdAddr = (UINT8 *) 0xffffffff; /* No RBD */ /* buffer size: */ pRfd->size = sizeof (pRfd->rxData) + sizeof (pRfd->destAddr) + sizeof (pRfd->sourceAddr) + sizeof (pRfd->length); sendCommand (CU_NOP, RU_START, ((UINT32)pRfd)); /* * Poll, can't use waitForInt (), as this step doesn't generate interrupts. */ i557Status = 0; /* Wait for timeout (i557Status changes) or RU_STAT is RU_READY */ for (delay = 0; (delay < MAX_DELAY) && (pSCB->cmdStat.bits.rus != RU_READY); delay++) ; /* Wait... */ if (pSCB->cmdStat.bits.rus != RU_READY) { printf ("failed. Status: 0x%04X.\n", pSCB->cmdStat.words.status); return (ERROR); } return (OK); } /* * Get packet ready to send out over the network. Buffer should be * ETHERMTU + sizeof(enet_addr) + sizeof(UINT16) */ static void setUpPacket (char *pBuf)/* Where to put it */ { memcpy (pBuf, node_address, sizeof(node_address)); pBuf += sizeof(node_address); /* skip dest. address */ *((UINT16 *) pBuf) = 0; pBuf += sizeof(UINT16); /* skip length field */ makePacket (pBuf, ETHERMTU); } /* Send and verify a packet using the current loopback mode. */ static int txPacket (char *pBuf) /* Dest addr, ethertype, buffer */ { int status = OK; /* Set up transmit command block and execute */ memset((char *) pCmdBlock, 0, sizeof(union cmdBlock)); pCmdBlock->transmit.code = TRANSMIT; pCmdBlock->transmit.el = END_OF_LIST; pCmdBlock->transmit.sf = 0; /* Simplified mode */ pCmdBlock->transmit.tbdAddr = (UINT8 *) 0xffffffff; /* No TBD */ pCmdBlock->transmit.eof = 1; /* Entire frame here */ /* # bytes to tx: */ pCmdBlock->transmit.tcbCount = sizeof (pCmdBlock->transmit.destAddr) + sizeof (pCmdBlock->transmit.length) + sizeof (pCmdBlock->transmit.txData); #if 0 printf ("destAddr size = %d\n", sizeof (pCmdBlock->transmit.destAddr)); printf ("length size = %d\n", sizeof (pCmdBlock->transmit.length)); printf ("Transmitting %d bytes\n", pCmdBlock->transmit.tcbCount); #endif memcpy (pCmdBlock->transmit.destAddr, pBuf, sizeof(node_address) + sizeof(UINT16) + ETHERMTU); rxSem = 0; /* no Receive interrupt */ sendCommand (CU_START, RU_NOP, ((UINT32)pCmdBlock)); if (waitForInt() == ERROR) { printf ("No Transmit Interrupt\n"); status = ERROR; } if (pCmdBlock->transmit.ok != 1) { printf ("tx failed. Status: 0x%04X.\n", pSCB->cmdStat.words.status); status = ERROR; } if (status == ERROR) { printf ("Transmit OK = %d\n", pCmdBlock->transmit.ok); return (ERROR); } #if 1 if (waitForRxInt() == ERROR) { printf ("No Receive Interrupt\n"); status = ERROR; } if (pRfd->ok != 1) { printf ("rx failed. Status: 0x%04X.\n", pSCB->cmdStat.words.status); status = ERROR; } #if 1 /* If RU still ready, hang for receive interrupt */ if (pSCB->cmdStat.bits.rus == RU_READY) { if (waitForRxInt() == ERROR) { printf ("No Receive Interrupt\n"); status = ERROR; } if (pRfd->ok != 1) { printf ("rx failed. Status: 0x%04X.\n", pSCB->cmdStat.words.status); status = ERROR; } } #endif if (status == ERROR) { printf ("\nTransmit Stats:\n"); printf ("---------------\n"); printf ("Transmit OK = %d\n", pCmdBlock->transmit.ok); printf ("\nReceive Stats:\n"); printf ("---------------\n\n"); printf ("Receive OK = %d\n", pRfd->ok); printf ("CRC Error = %d\n", pRfd->crcErr); printf ("Alignment Error = %d\n", pRfd->alignErr); printf ("Resource Error = %d\n", pRfd->noRsrc); printf ("DMA Overrun Error = %d\n", pRfd->dmaOverrun); printf ("Frame Too Short Error = %d\n", pRfd->frameTooshort); printf ("Receive Collision Error = %d\n", pRfd->rxColl); return (ERROR); } #if 0 printf ("Packet Actual Size = %d\n", pRfd->actCount); #endif if (checkPacket (pCmdBlock->transmit.txData, pRfd->rxData, ETHERMTU) == ERROR) { printf ("data verify error.\n"); return (ERROR); } if (forever_flag == FALSE) printf ("data OK.\n"); #endif return (OK); } /* * "Poor Man's Malloc" - return a pointer to a block of memory at least * The block returned will have been zeroed. */ static char *malloc (int numBytes) /* number of bytes needed */ { volatile char *rtnPtr; /* ptr to return to caller */ long new_mem_pool; /* For figuring new pool base address */ rtnPtr = mem_pool; /* Return pointer to start of free pool */ /* Now calculate new base of free memory pool (round to >= 16 bytes) */ new_mem_pool = (UINT32) mem_pool; new_mem_pool = ((new_mem_pool + numBytes + 0x10) & (~((UINT32) 0x0f))); mem_pool = (volatile char *) new_mem_pool; memset(rtnPtr, 0, numBytes); return ((char *) rtnPtr); } /* * Write "value" to PORT register of PRO/100. */ static void portWrite (UINT32 value) { *PORT_REG(adapter[0]) = value; } /****************************************************************************** * * sendCommand - send a command to the 82557 via the on-chip SCB * * Send a command to the 82557. On the 82557, the Channel Attention signal * has been replaced by an on-chip SCB. Accesses to the Command Word portion * of the SCB automatically forces the '557 to look at the various data * structures which make up its interface. */ static void sendCommand (UINT8 cuc, UINT8 ruc, UINT32 scb_general_ptr) { register CMD_STAT_U temp_cmdStat; volatile union cmdBlock *pBlock = (union cmdBlock *)scb_general_ptr; volatile int loop_ctr; /* Mask adapter interrupts to prevent the interrupt handler from playing with the SCB */ mask_557_ints(); /* must wait for the Command Unit to become idle to prevent us from issueing a CU_START to an active Command Unit */ for (loop_ctr = BUSY_WAIT_LIMIT; loop_ctr > 0; loop_ctr--) { if ((pSCB->cmdStat.words.status & SCB_S_CUMASK) == SCB_S_CUIDLE) break; } if (loop_ctr == 0) { printf("sendCommand: CU won't go idle, command ignored\n"); unmask_557_ints(); return; } /* when setting the command word, read the current word from the SCB and preserve the upper byte which contains the interrupt mask bit */ temp_cmdStat.words.command = (pSCB->cmdStat.words.command & 0xff00); temp_cmdStat.words.status = 0; /* set up the Command and Receive unit commands */ temp_cmdStat.bits.cuc = cuc & 0x07; temp_cmdStat.bits.ruc = ruc & 0x07; /* Clear flag */ waitSem = 0; /* write the General Pointer portion of the SCB first */ pSCB->scb_general_ptr = scb_general_ptr; /* write the Command Word of the SCB */ pSCB->cmdStat.words.command = temp_cmdStat.words.command; /* only wait for command which will complete immediately */ if ((scb_general_ptr != 0/* NULL*/) && (ruc != RU_START)) { /* wait for command acceptance and completion */ for (loop_ctr = BUSY_WAIT_LIMIT; loop_ctr > 0; loop_ctr--) { if ((pSCB->cmdStat.bits.cuc == 0) && (pBlock->nop.c == 1)) break; } if (loop_ctr == 0) { printf("sendCommand: Timeout on command complete\n"); printf("Cmd Complete bit = %02X\n", pBlock->nop.c); printf("CU command = 0x%02X\n", cuc); printf("RU command = 0x%02X\n", ruc); printf("SCB Gen Ptr = 0x%X\n", scb_general_ptr); printf("scb status = 0x%04X\n", pSCB->cmdStat.words.status); printf("scb command = 0x%04X\n", pSCB->cmdStat.words.command); } } #if 0 /* DEBUG */ printf("scb command = 0x%04X\n", pSCB->cmdStat.words.command); printf("scb status = 0x%04X\n", pSCB->cmdStat.words.status); #endif unmask_557_ints(); return; } /* * Do a port reset on 82557. */ static void resetChip (void) { portWrite (PORT_RESET); /* bits 4-31 not used for reset */ /* wait 5 msec for device to stabilize */ delay_ms(5); } /* * Setup contents of a packet. */ static void makePacket (UINT8 *pPacket, int length) { int byteNum; /* Current byte number */ for (byteNum = 0; byteNum < length; byteNum++) *pPacket++ = byteNum + ' '; } /* * Verify contents of a received packet to what was transmitted. * Returns OK if they match, ERROR if not. */ static int checkPacket (UINT8 *pTxBuffer, UINT8 *pRxBuffer, int length) { int byteNum; /* Current byte number */ for (byteNum = 0; byteNum < length; byteNum++) { if (*pTxBuffer++ != *pRxBuffer++) { printf("Error at byte 0x%x\n", byteNum); printf("Expected 0x%02X, got 0x%02X\n", *(pTxBuffer - 1), *(pRxBuffer - 1)); return (ERROR); } } return (OK); } /* * Interrupt handler for i82557. It acknowledges the interrupt * by setting the ACK bits in the command word and issuing a * channel attention. It then updates the global status variable * and gives the semaphore to wake up the main routine. */ int i557IntHandler (int arg) /* should return int */ { register CMD_STAT_U temp_cmdStat; register int rxFlag = FALSE; temp_cmdStat.words.status = pSCB->cmdStat.words.status; /* check to see if it was the PRO/100 */ if (temp_cmdStat.words.status & I557_INT) { /* Wait for command word to clear - indicates no pending commands */ while (pSCB->cmdStat.words.command) ; /* Update global status variable */ i557Status = temp_cmdStat.words.status; /* If the interrupt was due to a received frame... */ if (temp_cmdStat.bits.statack_fr) rxFlag = TRUE; temp_cmdStat.words.status = temp_cmdStat.words.status & I557_INT; /* Acknowledge interrupt by setting ack bits */ pSCB->cmdStat.words.status = temp_cmdStat.words.status; /* Wait for command word to clear - indicates IACK accepted */ while (pSCB->cmdStat.words.command) ; /* Update global status variable and unblock task */ waitSem = 1; if (rxFlag == TRUE) rxSem = 1; return(1); /* serviced - return 1 */ } return(0); /* nothing serviced - return 0 */ } /* * Take the semaphore and block until i557 interrupt or timeout. * Returns OK if an interrupt occured, ERROR if a timeout. */ static int waitForInt(void) { int num_ms = 0; while ((waitSem == 0) && (num_ms != 2000)) { /* wait max 2secs for the interrupt */ delay_ms(1); num_ms++; } if (!waitSem) { printf("Wait error!\n"); return (ERROR); } else return (OK); } static int waitForRxInt(void) { int num_ms = 0; while ((rxSem == 0) && (num_ms != 2000)) { /* wait max 2secs for the interrupt */ delay_ms(1); num_ms++; } if (!rxSem) { printf("Rx Wait error!\n"); return (ERROR); } else return (OK); } static UINT16 readMDI (int unit, UINT8 phyAdd, UINT8 regAdd) { register MDI_CONTROL_U mdiCtrl; int num_ms = 0; /* prepare for the MDI operation */ mdiCtrl.bits.ready = MDI_NOT_READY; mdiCtrl.bits.intEnab = MDI_POLLED; /* no interrupts */ mdiCtrl.bits.op = MDI_READ_OP; mdiCtrl.bits.phyAdd = phyAdd & 0x1f; mdiCtrl.bits.regAdd = regAdd & 0x1f; /* start the operation */ *MDI_CTL_REG(adapter[unit]) = mdiCtrl.word; /* delay a bit */ delay_ms(1); /* poll for completion */ mdiCtrl.word = *MDI_CTL_REG(adapter[unit]); while ((mdiCtrl.bits.ready == MDI_NOT_READY) && (num_ms != 2000)) { /* wait max 2secs */ mdiCtrl.word = *MDI_CTL_REG(adapter[unit]); delay_ms(1); num_ms++; } if (num_ms >= 2000) { printf ("readMDI Timeout!\n"); return (-1); } else return ((UINT16)mdiCtrl.bits.data); } static void writeMDI (int unit, UINT8 phyAdd, UINT8 regAdd, UINT16 data) { register MDI_CONTROL_U mdiCtrl; int num_ms = 0; /* prepare for the MDI operation */ mdiCtrl.bits.ready = MDI_NOT_READY; mdiCtrl.bits.intEnab = MDI_POLLED; /* no interrupts */ mdiCtrl.bits.op = MDI_WRITE_OP; mdiCtrl.bits.phyAdd = phyAdd & 0x1f; mdiCtrl.bits.regAdd = regAdd & 0x1f; mdiCtrl.bits.data = data & 0xffff; /* start the operation */ *MDI_CTL_REG(adapter[unit]) = mdiCtrl.word; /* delay a bit */ delay_ms(1); /* poll for completion */ mdiCtrl.word = *MDI_CTL_REG(adapter[unit]); while ((mdiCtrl.bits.ready == MDI_NOT_READY) && (num_ms != 2000)) { mdiCtrl.word = *MDI_CTL_REG(adapter[unit]); delay_ms(1); num_ms++; } if (num_ms >= 2000) printf ("writeMDI Timeout!\n"); return; } static int get_ether_addr (int unit, UINT8 *buffer, int print_flag) /* TRUE to print the information */ { UINT16 temp_node_addr[3] = {0,0,0}; register int i; /* Get the adapter's node address */ if (eeprom_read (adapter[unit],IA_OFFSET,temp_node_addr,3) != OK) { printf ("Error reading the IA address from Serial EEPROM.\n"); return (ERROR); } buffer[0] = (UINT8)(temp_node_addr[0] & 0x00ff); buffer[1] = (UINT8)((temp_node_addr[0] & 0xff00)>>8); buffer[2] = (UINT8)(temp_node_addr[1] & 0x00ff); buffer[3] = (UINT8)((temp_node_addr[1] & 0xff00)>>8); buffer[4] = (UINT8)(temp_node_addr[2] & 0x00ff); buffer[5] = (UINT8)((temp_node_addr[2] & 0xff00)>>8); if (print_flag == TRUE) { printf("Ethernet Address = [ "); for (i=0; i<6; i++) { printf("0x%02X ", buffer[i]); } printf("]\n\n"); } return (OK); }
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