URL
https://opencores.org/ocsvn/openrisc/openrisc/trunk
Subversion Repositories openrisc
[/] [openrisc/] [trunk/] [or1ksim/] [peripheral/] [eth.c] - Rev 431
Go to most recent revision | Compare with Previous | Blame | View Log
/* ethernet.c -- Simulation of Ethernet MAC Copyright (C) 2001 by Erez Volk, erez@opencores.org Ivan Guzvinec, ivang@opencores.org Copyright (C) 2008 Embecosm Limited Contributor Jeremy Bennett <jeremy.bennett@embecosm.com> This file is part of Or1ksim, the OpenRISC 1000 Architectural Simulator. This program is free software; you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation; either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see <http://www.gnu.org/licenses/>. */ /* This program is commented throughout in a fashion suitable for processing with Doxygen. */ /* Autoconf and/or portability configuration */ #include "config.h" #include "port.h" /* System includes */ #include <stdlib.h> #include <stdio.h> #include <sys/types.h> #include <sys/stat.h> #include <fcntl.h> #include <sys/poll.h> #include <sys/time.h> #include <unistd.h> #include <errno.h> #include <netinet/in.h> #include <sys/ioctl.h> #include <sys/socket.h> #include <net/if.h> /* Package includes */ #include "arch.h" #include "config.h" #include "abstract.h" #include "eth.h" #include "dma.h" #include "sim-config.h" #include "fields.h" #include "crc32.h" #include "vapi.h" #include "pic.h" #include "sched.h" #include "toplevel-support.h" #include "sim-cmd.h" struct eth_device { /* Is peripheral enabled */ int enabled; /* Base address in memory */ oraddr_t baseaddr; /* Which DMA controller is this MAC connected to */ unsigned dma; unsigned tx_channel; unsigned rx_channel; /* Our address */ unsigned char mac_address[ETHER_ADDR_LEN]; /* interrupt line */ unsigned long mac_int; /* VAPI ID */ unsigned long base_vapi_id; /* Ethernet PHY address */ unsigned long phy_addr; /* RX and TX file names and handles */ char *rxfile, *txfile; int txfd; int rxfd; off_t loopback_offset; /* Socket interface name */ char *sockif; int rtx_sock; int rtx_type; struct ifreq ifr; fd_set rfds, wfds; /* Current TX state */ struct { unsigned long state; unsigned long bd_index; unsigned long bd; unsigned long bd_addr; unsigned working, waiting_for_dma, error; long packet_length; unsigned minimum_length, maximum_length; unsigned add_crc; unsigned crc_dly; unsigned long crc_value; long bytes_left, bytes_sent; } tx; /* Current RX state */ struct { unsigned long state; unsigned long bd_index; unsigned long bd; unsigned long bd_addr; int fd; off_t *offset; unsigned working, error, waiting_for_dma; long packet_length, bytes_read, bytes_left; } rx; /* Visible registers */ struct { unsigned long moder; unsigned long int_source; unsigned long int_mask; unsigned long ipgt; unsigned long ipgr1; unsigned long ipgr2; unsigned long packetlen; unsigned long collconf; unsigned long tx_bd_num; unsigned long controlmoder; unsigned long miimoder; unsigned long miicommand; unsigned long miiaddress; unsigned long miitx_data; unsigned long miirx_data; unsigned long miistatus; unsigned long hash0; unsigned long hash1; /* Buffer descriptors */ unsigned long bd_ram[ETH_BD_SPACE / 4]; } regs; unsigned char rx_buff[ETH_MAXPL]; unsigned char tx_buff[ETH_MAXPL]; unsigned char lo_buff[ETH_MAXPL]; }; /* simulator interface */ static void eth_vapi_read (unsigned long id, unsigned long data, void *dat); /* register interface */ static void eth_write32 (oraddr_t addr, uint32_t value, void *dat); static uint32_t eth_read32 (oraddr_t addr, void *dat); /* clock */ static void eth_controller_tx_clock (void *); static void eth_controller_rx_clock (void *); /* utility functions */ static ssize_t eth_read_rx_file (struct eth_device *, void *, size_t); static void eth_skip_rx_file (struct eth_device *, off_t); static void eth_rx_next_packet (struct eth_device *); static void eth_write_tx_bd_num (struct eth_device *, unsigned long value); static void eth_miim_trans (void *dat); /* ========================================================================= */ /* TX LOGIC */ /*---------------------------------------------------------------------------*/ /* * TX clock * Responsible for starting and finishing TX */ static void eth_controller_tx_clock (void *dat) { struct eth_device *eth = dat; int bAdvance = 1; #if HAVE_ETH_PHY struct sockaddr_ll sll; #endif /* HAVE_ETH_PHY */ long nwritten = 0; unsigned long read_word; switch (eth->tx.state) { case ETH_TXSTATE_IDLE: eth->tx.state = ETH_TXSTATE_WAIT4BD; break; case ETH_TXSTATE_WAIT4BD: /* Read buffer descriptor */ eth->tx.bd = eth->regs.bd_ram[eth->tx.bd_index]; eth->tx.bd_addr = eth->regs.bd_ram[eth->tx.bd_index + 1]; if (TEST_FLAG (eth->tx.bd, ETH_TX_BD, READY)) { /*****************/ /* initialize TX */ eth->tx.bytes_left = eth->tx.packet_length = GET_FIELD (eth->tx.bd, ETH_TX_BD, LENGTH); eth->tx.bytes_sent = 0; /* Initialize error status bits */ CLEAR_FLAG (eth->tx.bd, ETH_TX_BD, DEFER); CLEAR_FLAG (eth->tx.bd, ETH_TX_BD, COLLISION); CLEAR_FLAG (eth->tx.bd, ETH_TX_BD, RETRANSMIT); CLEAR_FLAG (eth->tx.bd, ETH_TX_BD, UNDERRUN); CLEAR_FLAG (eth->tx.bd, ETH_TX_BD, NO_CARRIER); SET_FIELD (eth->tx.bd, ETH_TX_BD, RETRY, 0); /* Find out minimum length */ if (TEST_FLAG (eth->tx.bd, ETH_TX_BD, PAD) || TEST_FLAG (eth->regs.moder, ETH_MODER, PAD)) eth->tx.minimum_length = GET_FIELD (eth->regs.packetlen, ETH_PACKETLEN, MINFL); else eth->tx.minimum_length = eth->tx.packet_length; /* Find out maximum length */ if (TEST_FLAG (eth->regs.moder, ETH_MODER, HUGEN)) eth->tx.maximum_length = eth->tx.packet_length; else eth->tx.maximum_length = GET_FIELD (eth->regs.packetlen, ETH_PACKETLEN, MAXFL); /* Do we need CRC on this packet? */ if (TEST_FLAG (eth->regs.moder, ETH_MODER, CRCEN) || (TEST_FLAG (eth->tx.bd, ETH_TX_BD, CRC) && TEST_FLAG (eth->tx.bd, ETH_TX_BD, LAST))) eth->tx.add_crc = 1; else eth->tx.add_crc = 0; if (TEST_FLAG (eth->regs.moder, ETH_MODER, DLYCRCEN)) eth->tx.crc_dly = 1; else eth->tx.crc_dly = 0; /* XXX - For now we skip CRC calculation */ if (eth->rtx_type == ETH_RTX_FILE) { /* write packet length to file */ nwritten = write (eth->txfd, &(eth->tx.packet_length), sizeof (eth->tx.packet_length)); } /************************************************/ /* start transmit with reading packet into FIFO */ eth->tx.state = ETH_TXSTATE_READFIFO; } /* stay in this state if (TXEN && !READY) */ break; case ETH_TXSTATE_READFIFO: #if 1 if (eth->tx.bytes_sent < eth->tx.packet_length) { read_word = eval_direct32 (eth->tx.bytes_sent + eth->tx.bd_addr, 0, 0); eth->tx_buff[eth->tx.bytes_sent] = (unsigned char) (read_word >> 24); eth->tx_buff[eth->tx.bytes_sent + 1] = (unsigned char) (read_word >> 16); eth->tx_buff[eth->tx.bytes_sent + 2] = (unsigned char) (read_word >> 8); eth->tx_buff[eth->tx.bytes_sent + 3] = (unsigned char) (read_word); eth->tx.bytes_sent += 4; } #else if (eth->tx.bytes_sent < eth->tx.packet_length) { eth->tx_buff[eth->tx.bytes_sent] = eval_direct8 (eth->tx.bytes_sent + eth->tx.bd_addr, 0, 0); eth->tx.bytes_sent += 1; } #endif else { eth->tx.state = ETH_TXSTATE_TRANSMIT; } break; case ETH_TXSTATE_TRANSMIT: /* send packet */ switch (eth->rtx_type) { case ETH_RTX_FILE: nwritten = write (eth->txfd, eth->tx_buff, eth->tx.packet_length); break; #if HAVE_ETH_PHY case ETH_RTX_SOCK: memset (&sll, 0, sizeof (sll)); sll.sll_ifindex = eth->ifr.ifr_ifindex; nwritten = sendto (eth->rtx_sock, eth->tx_buff, eth->tx.packet_length, 0, (struct sockaddr *) &sll, sizeof (sll)); #endif /* HAVE_ETH_PHY */ } /* set BD status */ if (nwritten == eth->tx.packet_length) { CLEAR_FLAG (eth->tx.bd, ETH_TX_BD, READY); SET_FLAG (eth->regs.int_source, ETH_INT_SOURCE, TXB); eth->tx.state = ETH_TXSTATE_WAIT4BD; } else { /* XXX - implement retry mechanism here! */ CLEAR_FLAG (eth->tx.bd, ETH_TX_BD, READY); CLEAR_FLAG (eth->tx.bd, ETH_TX_BD, COLLISION); SET_FLAG (eth->regs.int_source, ETH_INT_SOURCE, TXE); eth->tx.state = ETH_TXSTATE_WAIT4BD; } eth->regs.bd_ram[eth->tx.bd_index] = eth->tx.bd; /* generate OK interrupt */ if (TEST_FLAG (eth->regs.int_mask, ETH_INT_MASK, TXE_M) || TEST_FLAG (eth->regs.int_mask, ETH_INT_MASK, TXB_M)) { if (TEST_FLAG (eth->tx.bd, ETH_TX_BD, IRQ)) report_interrupt (eth->mac_int); } /* advance to next BD */ if (bAdvance) { if (TEST_FLAG (eth->tx.bd, ETH_TX_BD, WRAP) || eth->tx.bd_index >= ETH_BD_COUNT) eth->tx.bd_index = 0; else eth->tx.bd_index += 2; } break; } /* Reschedule */ SCHED_ADD (eth_controller_tx_clock, dat, 1); } /* ========================================================================= */ /* ========================================================================= */ /* RX LOGIC */ /*---------------------------------------------------------------------------*/ /* * RX clock * Responsible for starting and finishing RX */ static void eth_controller_rx_clock (void *dat) { struct eth_device *eth = dat; long nread; unsigned long send_word; switch (eth->rx.state) { case ETH_RXSTATE_IDLE: eth->rx.state = ETH_RXSTATE_WAIT4BD; break; case ETH_RXSTATE_WAIT4BD: eth->rx.bd = eth->regs.bd_ram[eth->rx.bd_index]; eth->rx.bd_addr = eth->regs.bd_ram[eth->rx.bd_index + 1]; if (TEST_FLAG (eth->rx.bd, ETH_RX_BD, READY)) { /*****************/ /* Initialize RX */ CLEAR_FLAG (eth->rx.bd, ETH_RX_BD, MISS); CLEAR_FLAG (eth->rx.bd, ETH_RX_BD, INVALID); CLEAR_FLAG (eth->rx.bd, ETH_RX_BD, DRIBBLE); CLEAR_FLAG (eth->rx.bd, ETH_RX_BD, UVERRUN); CLEAR_FLAG (eth->rx.bd, ETH_RX_BD, COLLISION); CLEAR_FLAG (eth->rx.bd, ETH_RX_BD, TOOBIG); CLEAR_FLAG (eth->rx.bd, ETH_RX_BD, TOOSHORT); /* Setup file to read from */ if (TEST_FLAG (eth->regs.moder, ETH_MODER, LOOPBCK)) { eth->rx.fd = eth->txfd; eth->rx.offset = &(eth->loopback_offset); } else { eth->rx.fd = eth->rxfd; eth->rx.offset = 0; } eth->rx.state = ETH_RXSTATE_RECV; } else if (!TEST_FLAG (eth->regs.moder, ETH_MODER, RXEN)) { eth->rx.state = ETH_RXSTATE_IDLE; } else { nread = recv (eth->rtx_sock, eth->rx_buff, ETH_MAXPL, /*MSG_PEEK | */ MSG_DONTWAIT); if (nread > 0) { SET_FLAG (eth->regs.int_source, ETH_INT_SOURCE, BUSY); if (TEST_FLAG (eth->regs.int_mask, ETH_INT_MASK, BUSY_M)) report_interrupt (eth->mac_int); } } break; case ETH_RXSTATE_RECV: switch (eth->rtx_type) { case ETH_RTX_FILE: /* Read packet length */ if (eth_read_rx_file (eth, &(eth->rx.packet_length), sizeof (eth->rx.packet_length)) < sizeof (eth->rx.packet_length)) { /* TODO: just do what real ethernet would do (some kind of error state) */ sim_done (); break; } /* Packet must be big enough to hold a header */ if (eth->rx.packet_length < ETHER_HDR_LEN) { eth_rx_next_packet (eth); eth->rx.state = ETH_RXSTATE_WAIT4BD; break; } eth->rx.bytes_read = 0; eth->rx.bytes_left = eth->rx.packet_length; /* for now Read entire packet into memory */ nread = eth_read_rx_file (eth, eth->rx_buff, eth->rx.bytes_left); if (nread < eth->rx.bytes_left) { eth->rx.error = 1; break; } eth->rx.packet_length = nread; eth->rx.bytes_left = nread; eth->rx.bytes_read = 0; eth->rx.state = ETH_RXSTATE_WRITEFIFO; break; case ETH_RTX_SOCK: nread = recv (eth->rtx_sock, eth->rx_buff, ETH_MAXPL, MSG_DONTWAIT); if (nread == 0) { break; } else if (nread < 0) { if (errno != EAGAIN) { break; } else break; } /* If not promiscouos mode, check the destination address */ if (!TEST_FLAG (eth->regs.moder, ETH_MODER, PRO)) { if (TEST_FLAG (eth->regs.moder, ETH_MODER, IAM) && (eth->rx_buff[0] & 1)) { /* Nothing for now */ } if (eth->mac_address[5] != eth->rx_buff[0] || eth->mac_address[4] != eth->rx_buff[1] || eth->mac_address[3] != eth->rx_buff[2] || eth->mac_address[2] != eth->rx_buff[3] || eth->mac_address[1] != eth->rx_buff[4] || eth->mac_address[0] != eth->rx_buff[5]) break; } eth->rx.packet_length = nread; eth->rx.bytes_left = nread; eth->rx.bytes_read = 0; eth->rx.state = ETH_RXSTATE_WRITEFIFO; break; case ETH_RTX_VAPI: break; } break; case ETH_RXSTATE_WRITEFIFO: #if 1 send_word = ((unsigned long) eth->rx_buff[eth->rx.bytes_read] << 24) | ((unsigned long) eth->rx_buff[eth->rx.bytes_read + 1] << 16) | ((unsigned long) eth->rx_buff[eth->rx.bytes_read + 2] << 8) | ((unsigned long) eth->rx_buff[eth->rx.bytes_read + 3]); set_direct32 (eth->rx.bd_addr + eth->rx.bytes_read, send_word, 0, 0); /* update counters */ eth->rx.bytes_left -= 4; eth->rx.bytes_read += 4; #else set_direct8 (eth->rx.bd_addr + eth->rx.bytes_read, eth->rx_buff[eth->rx.bytes_read], 0, 0); eth->rx.bytes_left -= 1; eth->rx.bytes_read += 1; #endif if (eth->rx.bytes_left <= 0) { /* Write result to bd */ SET_FIELD (eth->rx.bd, ETH_RX_BD, LENGTH, eth->rx.packet_length); CLEAR_FLAG (eth->rx.bd, ETH_RX_BD, READY); SET_FLAG (eth->regs.int_source, ETH_INT_SOURCE, RXB); if (eth->rx.packet_length < (GET_FIELD (eth->regs.packetlen, ETH_PACKETLEN, MINFL) - 4)) SET_FLAG (eth->rx.bd, ETH_RX_BD, TOOSHORT); if (eth->rx.packet_length > GET_FIELD (eth->regs.packetlen, ETH_PACKETLEN, MAXFL)) SET_FLAG (eth->rx.bd, ETH_RX_BD, TOOBIG); eth->regs.bd_ram[eth->rx.bd_index] = eth->rx.bd; /* advance to next BD */ if (TEST_FLAG (eth->rx.bd, ETH_RX_BD, WRAP) || eth->rx.bd_index >= ETH_BD_COUNT) eth->rx.bd_index = eth->regs.tx_bd_num << 1; else eth->rx.bd_index += 2; if ((TEST_FLAG (eth->regs.int_mask, ETH_INT_MASK, RXB_M)) && (TEST_FLAG (eth->rx.bd, ETH_RX_BD, IRQ))) { report_interrupt (eth->mac_int); } /* ready to receive next packet */ eth->rx.state = ETH_RXSTATE_IDLE; } break; } /* Reschedule */ SCHED_ADD (eth_controller_rx_clock, dat, 1); } /* ========================================================================= */ /* Move to next RX BD */ static void eth_rx_next_packet (struct eth_device *eth) { /* Skip any possible leftovers */ if (eth->rx.bytes_left) eth_skip_rx_file (eth, eth->rx.bytes_left); } /* "Skip" bytes in RX file */ static void eth_skip_rx_file (struct eth_device *eth, off_t count) { eth->rx.offset += count; } /* * Utility function to read from the ethernet RX file * This function moves the file pointer to the current place in the packet before reading */ static ssize_t eth_read_rx_file (struct eth_device *eth, void *buf, size_t count) { ssize_t result; if (eth->rx.fd <= 0) { return 0; } if (eth->rx.offset) if (lseek (eth->rx.fd, *(eth->rx.offset), SEEK_SET) == (off_t) - 1) { return 0; } result = read (eth->rx.fd, buf, count); if (eth->rx.offset && result >= 0) *(eth->rx.offset) += result; return result; } /* ========================================================================= */ /* Reset. Initializes all registers to default and places devices in memory address space. */ static void eth_reset (void *dat) { struct eth_device *eth = dat; #if HAVE_ETH_PHY int j; struct sockaddr_ll sll; #endif /* HAVE_ETH_PHY */ if (eth->baseaddr != 0) { switch (eth->rtx_type) { case ETH_RTX_FILE: /* (Re-)open TX/RX files */ if (eth->rxfd > 0) close (eth->rxfd); if (eth->txfd > 0) close (eth->txfd); eth->rxfd = eth->txfd = -1; if ((eth->rxfd = open (eth->rxfile, O_RDONLY)) < 0) fprintf (stderr, "Cannot open Ethernet RX file \"%s\"\n", eth->rxfile); if ((eth->txfd = open (eth->txfile, O_RDWR | O_CREAT | O_APPEND #if defined(O_SYNC) /* BSD / Mac OS X manual doesn't know about O_SYNC */ | O_SYNC #endif , S_IRUSR | S_IWUSR | S_IRGRP | S_IROTH)) < 0) fprintf (stderr, "Cannot open Ethernet TX file \"%s\"\n", eth->txfile); eth->loopback_offset = lseek (eth->txfd, 0, SEEK_END); break; #if HAVE_ETH_PHY case ETH_RTX_SOCK: /* (Re-)open TX/RX sockets */ if (eth->rtx_sock != 0) break; eth->rtx_sock = socket (PF_PACKET, SOCK_RAW, htons (ETH_P_ALL)); if (eth->rtx_sock == -1) { fprintf (stderr, "Cannot open rtx_sock.\n"); return; } /* get interface index number */ memset (&(eth->ifr), 0, sizeof (eth->ifr)); strncpy (eth->ifr.ifr_name, eth->sockif, IFNAMSIZ); if (ioctl (eth->rtx_sock, SIOCGIFINDEX, &(eth->ifr)) == -1) { fprintf (stderr, "SIOCGIFINDEX failed!\n"); return; } /* Bind to interface... */ memset (&sll, 0xff, sizeof (sll)); sll.sll_family = AF_PACKET; /* allways AF_PACKET */ sll.sll_protocol = htons (ETH_P_ALL); sll.sll_ifindex = eth->ifr.ifr_ifindex; if (bind (eth->rtx_sock, (struct sockaddr *) &sll, sizeof (sll)) == -1) { fprintf (stderr, "Error bind().\n"); return; } /* first, flush all received packets. */ do { fd_set fds; struct timeval t; FD_ZERO (&fds); FD_SET (eth->rtx_sock, &fds); memset (&t, 0, sizeof (t)); j = select (FD_SETSIZE, &fds, NULL, NULL, &t); if (j > 0) recv (eth->rtx_sock, eth->rx_buff, j, 0); } while (j); break; #else /* HAVE_ETH_PHY */ case ETH_RTX_SOCK: fprintf (stderr, "Ethernet phy not enabled in this configuration. Configure with --enable-ethphy.\n"); exit (1); break; #endif /* HAVE_ETH_PHY */ } /* Set registers to default values */ /* Zero all registers */ memset (&(eth->regs), 0, sizeof (eth->regs)); /* Set those with non-zero reset defaults */ eth->regs.moder = 0x0000A000; eth->regs.ipgt = 0x00000012; eth->regs.ipgr1 = 0x0000000C; eth->regs.ipgr2 = 0x00000012; eth->regs.packetlen = 0x003C0600; eth->regs.collconf = 0x000F003F; eth->regs.miimoder = 0x00000064; eth->regs.tx_bd_num = 0x00000040; /* Initialize TX/RX status */ memset (&(eth->tx), 0, sizeof (eth->tx)); memset (&(eth->rx), 0, sizeof (eth->rx)); eth->rx.bd_index = eth->regs.tx_bd_num << 1; /* Initialize VAPI */ if (eth->base_vapi_id) { vapi_install_multi_handler (eth->base_vapi_id, ETH_NUM_VAPI_IDS, eth_vapi_read, dat); } } } /* ========================================================================= */ /* Print register values on stdout */ static void eth_status (void *dat) { struct eth_device *eth = dat; PRINTF ("\nEthernet MAC at 0x%" PRIxADDR ":\n", eth->baseaddr); PRINTF ("MODER : 0x%08lX\n", eth->regs.moder); PRINTF ("INT_SOURCE : 0x%08lX\n", eth->regs.int_source); PRINTF ("INT_MASK : 0x%08lX\n", eth->regs.int_mask); PRINTF ("IPGT : 0x%08lX\n", eth->regs.ipgt); PRINTF ("IPGR1 : 0x%08lX\n", eth->regs.ipgr1); PRINTF ("IPGR2 : 0x%08lX\n", eth->regs.ipgr2); PRINTF ("PACKETLEN : 0x%08lX\n", eth->regs.packetlen); PRINTF ("COLLCONF : 0x%08lX\n", eth->regs.collconf); PRINTF ("TX_BD_NUM : 0x%08lX\n", eth->regs.tx_bd_num); PRINTF ("CTRLMODER : 0x%08lX\n", eth->regs.controlmoder); PRINTF ("MIIMODER : 0x%08lX\n", eth->regs.miimoder); PRINTF ("MIICOMMAND : 0x%08lX\n", eth->regs.miicommand); PRINTF ("MIIADDRESS : 0x%08lX\n", eth->regs.miiaddress); PRINTF ("MIITX_DATA : 0x%08lX\n", eth->regs.miitx_data); PRINTF ("MIIRX_DATA : 0x%08lX\n", eth->regs.miirx_data); PRINTF ("MIISTATUS : 0x%08lX\n", eth->regs.miistatus); PRINTF ("MAC Address : %02X:%02X:%02X:%02X:%02X:%02X\n", eth->mac_address[0], eth->mac_address[1], eth->mac_address[2], eth->mac_address[3], eth->mac_address[4], eth->mac_address[5]); PRINTF ("HASH0 : 0x%08lX\n", eth->regs.hash0); PRINTF ("HASH1 : 0x%08lX\n", eth->regs.hash1); } /* ========================================================================= */ /* Read a register */ static uint32_t eth_read32 (oraddr_t addr, void *dat) { struct eth_device *eth = dat; switch (addr) { case ETH_MODER: return eth->regs.moder; case ETH_INT_SOURCE: return eth->regs.int_source; case ETH_INT_MASK: return eth->regs.int_mask; case ETH_IPGT: return eth->regs.ipgt; case ETH_IPGR1: return eth->regs.ipgr1; case ETH_IPGR2: return eth->regs.ipgr2; case ETH_PACKETLEN: return eth->regs.packetlen; case ETH_COLLCONF: return eth->regs.collconf; case ETH_TX_BD_NUM: return eth->regs.tx_bd_num; case ETH_CTRLMODER: return eth->regs.controlmoder; case ETH_MIIMODER: return eth->regs.miimoder; case ETH_MIICOMMAND: return eth->regs.miicommand; case ETH_MIIADDRESS: return eth->regs.miiaddress; case ETH_MIITX_DATA: return eth->regs.miitx_data; case ETH_MIIRX_DATA: /*printf("or1ksim: read MIIM RX: 0x%x\n",(int)eth->regs.miirx_data);*/ return eth->regs.miirx_data; case ETH_MIISTATUS: return eth->regs.miistatus; case ETH_MAC_ADDR0: return (((unsigned long) eth->mac_address[3]) << 24) | (((unsigned long) eth->mac_address[2]) << 16) | (((unsigned long) eth->mac_address[1]) << 8) | (unsigned long) eth->mac_address[0]; case ETH_MAC_ADDR1: return (((unsigned long) eth->mac_address[5]) << 8) | (unsigned long) eth->mac_address[4]; case ETH_HASH0: return eth->regs.hash0; case ETH_HASH1: return eth->regs.hash1; /*case ETH_DMA_RX_TX: return eth_rx( eth ); */ } if ((addr >= ETH_BD_BASE) && (addr < ETH_BD_BASE + ETH_BD_SPACE)) return eth->regs.bd_ram[(addr - ETH_BD_BASE) / 4]; PRINTF ("eth_read32( 0x%" PRIxADDR " ): Illegal address\n", addr + eth->baseaddr); return 0; } /* ========================================================================= */ /* Write a register */ static void eth_write32 (oraddr_t addr, uint32_t value, void *dat) { struct eth_device *eth = dat; switch (addr) { case ETH_MODER: if (!TEST_FLAG (eth->regs.moder, ETH_MODER, RXEN) && TEST_FLAG (value, ETH_MODER, RXEN)) SCHED_ADD (eth_controller_rx_clock, dat, 1); else if (!TEST_FLAG (value, ETH_MODER, RXEN)) SCHED_FIND_REMOVE (eth_controller_rx_clock, dat); if (!TEST_FLAG (eth->regs.moder, ETH_MODER, TXEN) && TEST_FLAG (value, ETH_MODER, TXEN)) SCHED_ADD (eth_controller_tx_clock, dat, 1); else if (!TEST_FLAG (value, ETH_MODER, TXEN)) SCHED_FIND_REMOVE (eth_controller_tx_clock, dat); eth->regs.moder = value; if (TEST_FLAG (value, ETH_MODER, RST)) eth_reset (dat); return; case ETH_INT_SOURCE: if (!(eth->regs.int_source & ~value) && eth->regs.int_source) clear_interrupt (eth->mac_int); eth->regs.int_source &= ~value; return; case ETH_INT_MASK: eth->regs.int_mask = value; return; case ETH_IPGT: eth->regs.ipgt = value; return; case ETH_IPGR1: eth->regs.ipgr1 = value; return; case ETH_IPGR2: eth->regs.ipgr2 = value; return; case ETH_PACKETLEN: eth->regs.packetlen = value; return; case ETH_COLLCONF: eth->regs.collconf = value; return; case ETH_TX_BD_NUM: eth_write_tx_bd_num (eth, value); return; case ETH_CTRLMODER: eth->regs.controlmoder = value; return; case ETH_MIIMODER: eth->regs.miimoder = value; return; case ETH_MIICOMMAND: eth->regs.miicommand = value; /* Perform MIIM transaction, if required */ eth_miim_trans(dat); return; case ETH_MIIADDRESS: eth->regs.miiaddress = value; return; case ETH_MIITX_DATA: eth->regs.miitx_data = value; return; case ETH_MIIRX_DATA: /* Register is R/O eth->regs.miirx_data = value; */ return; case ETH_MIISTATUS: /* Register is R/O eth->regs.miistatus = value; */ return; case ETH_MAC_ADDR0: eth->mac_address[0] = value & 0xFF; eth->mac_address[1] = (value >> 8) & 0xFF; eth->mac_address[2] = (value >> 16) & 0xFF; eth->mac_address[3] = (value >> 24) & 0xFF; return; case ETH_MAC_ADDR1: eth->mac_address[4] = value & 0xFF; eth->mac_address[5] = (value >> 8) & 0xFF; return; case ETH_HASH0: eth->regs.hash0 = value; return; case ETH_HASH1: eth->regs.hash1 = value; return; /*case ETH_DMA_RX_TX: eth_tx( eth, value ); return; */ } if ((addr >= ETH_BD_BASE) && (addr < ETH_BD_BASE + ETH_BD_SPACE)) { eth->regs.bd_ram[(addr - ETH_BD_BASE) / 4] = value; return; } PRINTF ("eth_write32( 0x%" PRIxADDR " ): Illegal address\n", addr + eth->baseaddr); return; } /* ========================================================================= */ /* * VAPI connection to outside */ static void eth_vapi_read (unsigned long id, unsigned long data, void *dat) { unsigned long which; struct eth_device *eth = dat; which = id - eth->base_vapi_id; if (!eth) { return; } switch (which) { case ETH_VAPI_DATA: break; case ETH_VAPI_CTRL: break; } } /* ========================================================================= */ /* When TX_BD_NUM is written, also reset current RX BD index */ static void eth_write_tx_bd_num (struct eth_device *eth, unsigned long value) { eth->regs.tx_bd_num = value & 0xFF; eth->rx.bd_index = eth->regs.tx_bd_num << 1; } /* ========================================================================= */ /*-----------------------------------------------[ Ethernet configuration ]---*/ /*---------------------------------------------------------------------------*/ /*!Enable or disable the Ethernet interface @param[in] val The value to use @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_enabled (union param_val val, void *dat) { struct eth_device *eth = dat; eth->enabled = val.int_val; } /* eth_enabled() */ /*---------------------------------------------------------------------------*/ /*!Set the Ethernet interface base address @param[in] val The value to use @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_baseaddr (union param_val val, void *dat) { struct eth_device *eth = dat; eth->baseaddr = val.addr_val; } /* eth_baseaddr() */ /*---------------------------------------------------------------------------*/ /*!Set the Ethernet DMA port This is not currently supported, so a warning message is printed. @param[in] val The value to use @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_dma (union param_val val, void *dat) { struct eth_device *eth = dat; fprintf (stderr, "Warning: External Ethernet DMA not currently supported\n"); eth->dma = val.addr_val; } /* eth_dma() */ /*---------------------------------------------------------------------------*/ /*!Set the Ethernet IRQ @param[in] val The value to use @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_irq (union param_val val, void *dat) { struct eth_device *eth = dat; eth->mac_int = val.int_val; } /* eth_irq() */ /*---------------------------------------------------------------------------*/ /*!Set the Ethernet interface type Currently two types are supported, file and socket. Use of the socket requires a compile time option. @param[in] val The value to use. 0 for file, 1 for socket. @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_rtx_type (union param_val val, void *dat) { struct eth_device *eth = dat; if (val.int_val) { #ifndef HAVE_ETH_PHY fprintf (stderr, "Warning: Ethernet PHY socket not enabled in this " "configuration (configure with --enable-ethphy): ignored\n"); return; #endif } eth->rtx_type = val.int_val; } /* eth_rtx_type() */ /*---------------------------------------------------------------------------*/ /*!Set the Ethernet DMA Rx channel External DMA is not currently supported, so a warning message is printed. @param[in] val The value to use @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_rx_channel (union param_val val, void *dat) { struct eth_device *eth = dat; fprintf (stderr, "Warning: External Ethernet DMA not currently supported: " "Rx channel ignored\n"); eth->rx_channel = val.int_val; } /* eth_rx_channel() */ /*---------------------------------------------------------------------------*/ /*!Set the Ethernet DMA Tx channel External DMA is not currently supported, so a warning message is printed. @param[in] val The value to use @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_tx_channel (union param_val val, void *dat) { struct eth_device *eth = dat; fprintf (stderr, "Warning: External Ethernet DMA not currently supported: " "Tx channel ignored\n"); eth->tx_channel = val.int_val; } /* eth_tx_channel() */ /*---------------------------------------------------------------------------*/ /*!Set the Ethernet DMA Rx file Free any previously allocated value. @param[in] val The value to use @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_rxfile (union param_val val, void *dat) { struct eth_device *eth = dat; if (NULL != eth->rxfile) { free (eth->rxfile); eth->rxfile = NULL; } if (!(eth->rxfile = strdup (val.str_val))) { fprintf (stderr, "Peripheral Ethernet: Run out of memory\n"); exit (-1); } } /* eth_rxfile() */ /*---------------------------------------------------------------------------*/ /*!Set the Ethernet DMA Tx file Free any previously allocated value. @param[in] val The value to use @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_txfile (union param_val val, void *dat) { struct eth_device *eth = dat; if (NULL != eth->txfile) { free (eth->txfile); eth->txfile = NULL; } if (!(eth->txfile = strdup (val.str_val))) { fprintf (stderr, "Peripheral Ethernet: Run out of memory\n"); exit (-1); } } /* eth_txfile() */ /*---------------------------------------------------------------------------*/ /*!Set the Ethernet socket interface Free any previously allocated value. This is only meaningful if the socket interface is configured. @param[in] val The value to use @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_sockif (union param_val val, void *dat) { struct eth_device *eth = dat; #ifndef HAVE_ETH_PHY fprintf (stderr, "Warning: Ethernet PHY socket not enabled in this " "configuration (configure with --enable-ethphy): " "sockif ignored\n"); return; #endif if (NULL != eth->sockif) { free (eth->sockif); eth->sockif = NULL; } if (!(eth->sockif = strdup (val.str_val))) { fprintf (stderr, "Peripheral Ethernet: Run out of memory\n"); exit (-1); } } /* eth_sockif() */ static void eth_vapi_id (union param_val val, void *dat) { struct eth_device *eth = dat; eth->base_vapi_id = val.int_val; } static void eth_phy_addr (union param_val val, void *dat) { struct eth_device *eth = dat; eth->phy_addr = val.int_val & ETH_MIIADDR_FIAD_MASK; } /*---------------------------------------------------------------------------*/ /*!Emulate MIIM transaction to ethernet PHY @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_miim_trans (void *dat) { struct eth_device *eth = dat; switch (eth->regs.miicommand) { case ((1 << ETH_MIICOMM_WCDATA_OFFSET)): /* Perhaps something to emulate here later, but for now do nothing */ break; case ((1 << ETH_MIICOMM_RSTAT_OFFSET)): /* printf("or1ksim: eth_miim_trans: phy %d\n",(int) ((eth->regs.miiaddress >> ETH_MIIADDR_FIAD_OFFSET)& ETH_MIIADDR_FIAD_MASK)); printf("or1ksim: eth_miim_trans: reg %d\n",(int) ((eth->regs.miiaddress >> ETH_MIIADDR_RGAD_OFFSET)& ETH_MIIADDR_RGAD_MASK)); */ /*First check if it's the correct PHY to address */ if (((eth->regs.miiaddress >> ETH_MIIADDR_FIAD_OFFSET)& ETH_MIIADDR_FIAD_MASK) == eth->phy_addr) { /* Correct PHY - now switch based on the register address in the PHY*/ switch ((eth->regs.miiaddress >> ETH_MIIADDR_RGAD_OFFSET)& ETH_MIIADDR_RGAD_MASK) { case MII_BMCR: eth->regs.miirx_data = BMCR_FULLDPLX; break; case MII_BMSR: eth->regs.miirx_data = BMSR_LSTATUS | BMSR_ANEGCOMPLETE | BMSR_10HALF | BMSR_10FULL | BMSR_100HALF | BMSR_100FULL; break; case MII_PHYSID1: eth->regs.miirx_data = 0x22; /* Micrel PHYID */ break; case MII_PHYSID2: eth->regs.miirx_data = 0x1613; /* Micrel PHYID */ break; case MII_ADVERTISE: eth->regs.miirx_data = 0; break; case MII_LPA: eth->regs.miirx_data = LPA_DUPLEX | LPA_100; break; case MII_EXPANSION: eth->regs.miirx_data = 0; break; case MII_CTRL1000: eth->regs.miirx_data = 0; break; case MII_STAT1000: eth->regs.miirx_data = 0; break; case MII_ESTATUS: eth->regs.miirx_data = 0; break; case MII_DCOUNTER: eth->regs.miirx_data = 0; break; case MII_FCSCOUNTER: eth->regs.miirx_data = 0; break; case MII_NWAYTEST: eth->regs.miirx_data = 0; break; case MII_RERRCOUNTER: eth->regs.miirx_data = 0; break; case MII_SREVISION: eth->regs.miirx_data = 0; break; case MII_RESV1: eth->regs.miirx_data = 0; break; case MII_LBRERROR: eth->regs.miirx_data = 0; break; case MII_PHYADDR: eth->regs.miirx_data = eth->phy_addr; break; case MII_RESV2: eth->regs.miirx_data = 0; break; case MII_TPISTATUS: eth->regs.miirx_data = 0; break; case MII_NCONFIG: eth->regs.miirx_data = 0; break; default: eth->regs.miirx_data = 0xffff; break; } } else eth->regs.miirx_data = 0xffff; /* PHY doesn't exist, read all 1's */ break; case ((1 << ETH_MIICOMM_SCANS_OFFSET)): /* From MAC's datasheet: A host initiates the Scan Status Operation by asserting the SCANSTAT signal. The MIIM performs a continuous read operation of the PHY Status register. The PHY is selected by the FIAD[4:0] signals. The link status LinkFail signal is asserted/deasserted by the MIIM module and reflects the link status bit of the PHY Status register. The signal NVALID is used for qualifying the validity of the LinkFail signals and the status data PRSD[15:0]. These signals are invalid until the first scan status operation ends. During the scan status operation, the BUSY signal is asserted until the last read is performed (the scan status operation is stopped). So for now - do nothing, leave link status indicator as permanently with link. */ break; default: break; } } /*---------------------------------------------------------------------------*/ /*!Initialize a new Ethernet configuration ALL parameters are set explicitly to default values. */ /*---------------------------------------------------------------------------*/ static void * eth_sec_start (void) { struct eth_device *new = malloc (sizeof (struct eth_device)); if (!new) { fprintf (stderr, "Peripheral Eth: Run out of memory\n"); exit (-1); } memset (new, 0, sizeof (struct eth_device)); new->enabled = 1; new->baseaddr = 0; new->dma = 0; new->mac_int = 0; new->rtx_type = 0; new->rx_channel = 0; new->tx_channel = 0; new->rxfile = strdup ("eth_rx"); new->txfile = strdup ("eth_tx"); new->sockif = strdup ("or1ksim_eth"); new->base_vapi_id = 0; new->phy_addr = 0; return new; } static void eth_sec_end (void *dat) { struct eth_device *eth = dat; struct mem_ops ops; if (!eth->enabled) { free (eth->rxfile); free (eth->txfile); free (eth->sockif); free (eth); return; } memset (&ops, 0, sizeof (struct mem_ops)); ops.readfunc32 = eth_read32; ops.writefunc32 = eth_write32; ops.read_dat32 = dat; ops.write_dat32 = dat; /* FIXME: Correct delay? */ ops.delayr = 2; ops.delayw = 2; reg_mem_area (eth->baseaddr, ETH_ADDR_SPACE, 0, &ops); reg_sim_stat (eth_status, dat); reg_sim_reset (eth_reset, dat); } /*---------------------------------------------------------------------------*/ /*!Register a new Ethernet configuration */ /*---------------------------------------------------------------------------*/ void reg_ethernet_sec () { struct config_section *sec = reg_config_sec ("ethernet", eth_sec_start, eth_sec_end); reg_config_param (sec, "enabled", PARAMT_INT, eth_enabled); reg_config_param (sec, "baseaddr", PARAMT_ADDR, eth_baseaddr); reg_config_param (sec, "dma", PARAMT_INT, eth_dma); reg_config_param (sec, "irq", PARAMT_INT, eth_irq); reg_config_param (sec, "rtx_type", PARAMT_INT, eth_rtx_type); reg_config_param (sec, "rx_channel", PARAMT_INT, eth_rx_channel); reg_config_param (sec, "tx_channel", PARAMT_INT, eth_tx_channel); reg_config_param (sec, "rxfile", PARAMT_STR, eth_rxfile); reg_config_param (sec, "txfile", PARAMT_STR, eth_txfile); reg_config_param (sec, "sockif", PARAMT_STR, eth_sockif); reg_config_param (sec, "vapi_id", PARAMT_INT, eth_vapi_id); reg_config_param (sec, "phy_addr", PARAMT_INT, eth_phy_addr); } /* reg_ethernet_sec() */
Go to most recent revision | Compare with Previous | Blame | View Log