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[/] [openrisc/] [trunk/] [or1ksim/] [peripheral/] [eth.c] - Rev 774
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/* ethernet.c -- Simulation of Ethernet MAC Copyright (C) 2001 by Erez Volk, erez@opencores.org Ivan Guzvinec, ivang@opencores.org Copyright (C) 2008, 2001 Embecosm Limited Copyright (C) 2010 ORSoC Contributor Jeremy Bennett <jeremy.bennett@embecosm.com> Contributor Julius Baxter <julius@orsoc.se> 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/socket.h> #include <sys/ioctl.h> #include <sys/stat.h> #include <sys/types.h> #include <fcntl.h> #include <sys/poll.h> #include <unistd.h> #include <errno.h> #if HAVE_LINUX_IF_TUN_H==1 #include <linux/if.h> #include <linux/if_tun.h> #endif /* 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" /* Control debug messages */ #define ETH_DEBUG 0 #ifndef ETH_DEBUG # define ETH_DEBUG 1 #endif /*! Period (clock cycles) for rescheduling Rx and Tx controllers. Experimenting with FTP on one machine suggests that a value of 500-2000 is optimal. It's a trade off between prompt response and extra computational load for Or1ksim. */ #define RTX_RESCHED_PERIOD 2000 /*! MAC address that is always accepted. */ static const unsigned char mac_broadcast[ETHER_ADDR_LEN] = { 0xff, 0xff, 0xff, 0xff, 0xff, 0xff }; /* -------------------------------------------------------------------------- */ /*!Structure describing the Ethernet device */ /* -------------------------------------------------------------------------- */ struct eth_device { /* Basic stuff about the device */ int enabled; /* Is peripheral enabled */ oraddr_t baseaddr; /* Base address in memory */ unsigned long int base_vapi_id; /* Start of VAPI ID block */ /* DMA controller this MAC is connected to, and associated channels */ unsigned dma; unsigned tx_channel; unsigned rx_channel; /* Details of the hardware */ unsigned char mac_address[ETHER_ADDR_LEN]; /* Ext HW address */ unsigned long int phy_addr; /* Int HW address */ unsigned long int mac_int; /* interrupt line number */ int dummy_crc; /* Flag indicating if we add CRC */ int int_line_stat; /* interrupt line status */ /* External interface deatils */ int rtx_type; /* Type of external i/f: FILE or TAP */ /* RX and TX file names and handles for FILE type connection. */ char *rxfile; /* Rx filename */ char *txfile; /* Tx filename */ int txfd; /* Rx file handle */ int rxfd; /* Tx file handle */ /* Info for TAP type connections */ char *tap_dev; /* The TAP device */ int rtx_fd; /* TAP device handle */ /* Indices into the buffer descriptors. */ unsigned long int tx_bd_index; unsigned long int rx_bd_index; /* Visible registers */ struct { unsigned long int moder; unsigned long int int_source; unsigned long int int_mask; unsigned long int ipgt; unsigned long int ipgr1; unsigned long int ipgr2; unsigned long int packetlen; unsigned long int collconf; unsigned long int tx_bd_num; unsigned long int controlmoder; unsigned long int miimoder; unsigned long int miicommand; unsigned long int miiaddress; unsigned long int miitx_data; unsigned long int miirx_data; unsigned long int miistatus; unsigned long int hash0; unsigned long int hash1; /* Buffer descriptors */ unsigned long int bd_ram[ETH_BD_SPACE / 4]; } regs; }; /* -------------------------------------------------------------------------- */ /*!Write an Ethernet packet to a FILE interface. This writes a single Ethernet packet to a FILE interface. The format is to write the length, then the data. @param[in] eth Pointer to the relevant Ethernet data structure. @param[in] buf Where to get the data. @param[in] length Length of data to write. @return The length if successful, a negative value otherwise. */ /* -------------------------------------------------------------------------- */ static ssize_t eth_write_file_packet (struct eth_device *eth, unsigned char *buf, int32_t length) { ssize_t nwritten; /* Write length to file. */ nwritten = write (eth->txfd, &(length), sizeof (length)); if (nwritten != sizeof (length)) { fprintf (stderr, "ERROR: Failed to write Ethernet packet length: %s.\n", strerror (errno)); return -1; } /* write data to file */ nwritten = write (eth->txfd, buf, length); if (nwritten != length) { fprintf (stderr, "ERROR: Failed to write Ethernet packet data: %s.\n", strerror (errno)); return -1; } return nwritten; } /* eth_write_file_packet () */ #if HAVE_LINUX_IF_TUN_H==1 /* -------------------------------------------------------------------------- */ /*!Write an Ethernet packet to a TAP interface. This writes a single Ethernet packet to a TAP interface. @param[in] eth Pointer to the relevant Ethernet data structure. @param[in] buf Where to get the data. @param[in] length Length of data to write. @return The length if successful, a negative value otherwise. */ /* -------------------------------------------------------------------------- */ static ssize_t eth_write_tap_packet (struct eth_device *eth, unsigned char *buf, unsigned long int length) { ssize_t nwritten = 0; #if ETH_DEBUG int j; printf ("Writing TAP\n"); printf (" packet %d bytes:", (int) length); for (j = 0; j < length; j++) { if (0 == (j % 16)) { printf ("\n"); } else if (0 == (j % 8)) { printf (" "); } printf ("%.2x ", buf[j]); } printf("\nend packet:\n"); #endif /* Write the data to the TAP */ nwritten = write (eth->rtx_fd, buf, length); if (nwritten != length) { fprintf (stderr, "ERROR: Failed to write Ethernet packet data: %s.\n", strerror (errno)); return -1; } return nwritten; } /* eth_write_tap_packet () */ #endif /* -------------------------------------------------------------------------- */ /*!Write an Ethernet packet. This writes a single Ethernet packet to the outside world from the supplied buffer. It deals with the different types of external interface. @param[in] eth Pointer to the relevant Ethernet data structure. @param[in] buf Where to get the data. @param[in] length Length of data to write. @return The length if successful, zero if no packet was available, a negative value otherwise. */ /* -------------------------------------------------------------------------- */ static ssize_t eth_write_packet (struct eth_device *eth, unsigned char *buf, ssize_t length) { /* Send packet according to interface type. */ switch (eth->rtx_type) { case ETH_RTX_FILE: return eth_write_file_packet (eth, buf, length); #if HAVE_LINUX_IF_TUN_H==1 case ETH_RTX_TAP: return eth_write_tap_packet (eth, buf, length); #endif default: fprintf (stderr, "Unknown Ethernet write interface: ignored.\n"); return (ssize_t) -1; } } /* eth_write_packet () */ /* -------------------------------------------------------------------------- */ /*!Flush a Tx buffer descriptor to the outside world. We know the buffer descriptor is full, so write it to the appropriate outside interface. @param[in] eth The Ethernet data structure. */ /* -------------------------------------------------------------------------- */ static void eth_flush_bd (struct eth_device *eth) { /* First word of BD is flags and length, second is pointer to buffer */ unsigned long int bd_info = eth->regs.bd_ram[eth->tx_bd_index]; unsigned long int bd_addr = eth->regs.bd_ram[eth->tx_bd_index + 1]; unsigned char buf[ETH_MAXPL]; long int packet_length; long int bytes_sent; int ok_to_int_p; /* Get the packet length */ packet_length = GET_FIELD (bd_info, ETH_TX_BD, LENGTH); /* Clear error status bits and retry count. */ CLEAR_FLAG (bd_info, ETH_TX_BD, DEFER); CLEAR_FLAG (bd_info, ETH_TX_BD, COLLISION); CLEAR_FLAG (bd_info, ETH_TX_BD, RETRANSMIT); CLEAR_FLAG (bd_info, ETH_TX_BD, UNDERRUN); CLEAR_FLAG (bd_info, ETH_TX_BD, NO_CARRIER); SET_FIELD (bd_info, ETH_TX_BD, RETRY, 0); /* Copy data from buffer descriptor address into our local buf. */ for (bytes_sent = 0; bytes_sent < packet_length; bytes_sent +=4) { unsigned long int read_word = eval_direct32 (bytes_sent + bd_addr, 0, 0); buf[bytes_sent] = (unsigned char) (read_word >> 24); buf[bytes_sent + 1] = (unsigned char) (read_word >> 16); buf[bytes_sent + 2] = (unsigned char) (read_word >> 8); buf[bytes_sent + 3] = (unsigned char) (read_word); } /* Send packet according to interface type and set BD status. If we didn't write the whole packet, then we retry. */ if (eth_write_packet (eth, buf, packet_length) == packet_length) { CLEAR_FLAG (bd_info, ETH_TX_BD, READY); SET_FLAG (eth->regs.int_source, ETH_INT_SOURCE, TXB); ok_to_int_p = TEST_FLAG (eth->regs.int_mask, ETH_INT_MASK, TXB_M); } else { /* Does this retry mechanism really work? */ CLEAR_FLAG (bd_info, ETH_TX_BD, READY); CLEAR_FLAG (bd_info, ETH_TX_BD, COLLISION); SET_FLAG (eth->regs.int_source, ETH_INT_SOURCE, TXE); ok_to_int_p = TEST_FLAG (eth->regs.int_mask, ETH_INT_MASK, TXE_M); #if ETH_DEBUG printf ("Transmit retry request.\n"); #endif } /* Update the flags in the buffer descriptor */ eth->regs.bd_ram[eth->tx_bd_index] = bd_info; /* Generate interrupt to indicate transfer complete, under the following criteria all being met: - either INT_MASK flag for Tx (OK or error) is set - the buffer descriptor has its IRQ flag set - there is no interrupt in progress. @todo We ought to warn if we get here and fail to set an IRQ. */ if (ok_to_int_p && TEST_FLAG (bd_info, ETH_TX_BD, IRQ)) { if (eth->int_line_stat) { fprintf (stderr, "Warning: Interrupt active during Tx.\n"); } else { #if ETH_DEBUG printf ("TRANSMIT interrupt\n"); #endif report_interrupt (eth->mac_int); eth->int_line_stat = 1; } } /* Advance to next BD, wrapping around if appropriate. */ if (TEST_FLAG (bd_info, ETH_TX_BD, WRAP) || eth->tx_bd_index >= ((eth->regs.tx_bd_num - 1) * 2)) { eth->tx_bd_index = 0; } else { eth->tx_bd_index += 2; } } /* eth_flush_bd () */ /* -------------------------------------------------------------------------- */ /*!Tx clock function. Responsible for starting and completing any TX actions. The original version had 4 states, which allowed modeling the transfer of data one byte per cycle. For now we use only the one state for efficiency. When we find something in a buffer descriptor, we transmit it. We reschedule every cycle. There is no point in trying to do anything if there is an interrupt still being processed by the core. @todo We should eventually reinstate the one byte per cycle transfer. @param[in] dat The Ethernet data structure, passed as a void pointer. */ /* -------------------------------------------------------------------------- */ static void eth_controller_tx_clock (void *dat) { struct eth_device *eth = dat; /* Only do anything if there is not an interrupt outstanding. */ if (!eth->int_line_stat) { /* First word of BD is flags. If we have a buffer ready, get it and transmit it. */ if (TEST_FLAG (eth->regs.bd_ram[eth->tx_bd_index], ETH_TX_BD, READY)) { eth_flush_bd (eth); } } /* Reschedule to wake up again. */ SCHED_ADD (eth_controller_tx_clock, dat, RTX_RESCHED_PERIOD); } /* eth_controller_tx_clock () */ /* -------------------------------------------------------------------------- */ /*!Read an Ethernet packet from a FILE interface. This reads a single Ethernet packet from the outside world via a FILE interface. The format is 4 bytes of packet length, followed by the packet data. @param[in] eth Pointer to the relevant Ethernet data structure @param[out] buf Where to put the data @return The length if successful, zero if no packet was available (i.e. EOF), a negative value otherwise. */ /* -------------------------------------------------------------------------- */ static ssize_t eth_read_file_packet (struct eth_device *eth, unsigned char *buf) { int32_t packet_length; ssize_t nread; /* Read packet length. We may be at EOF. */ nread = read (eth->rxfd, &(packet_length), sizeof (packet_length)); if (0 == nread) { return 0; /* No more packets */ } else if (nread < sizeof (packet_length)) { fprintf (stderr, "ERROR: Failed to read length from file.\n"); return -1; } /* Packet must be big enough to hold a header */ if (packet_length < ETHER_HDR_LEN) { fprintf (stderr, "Warning: Ethernet packet length %d too small.\n", packet_length); return -1; } /* Read the packet proper. */ nread = read (eth->rxfd, buf, packet_length); if (nread != packet_length) { fprintf (stderr, "ERROR: Failed to read packet from file.\n"); return -1; } return (ssize_t)packet_length; } /* eth_read_file_packet () */ #if HAVE_LINUX_IF_TUN_H==1 /* -------------------------------------------------------------------------- */ /*!Read an Ethernet packet from a FILE interface. This reads a single Ethernet packet from the outside world via a TAP interface. A complete packet is always read, so its length (minus CRC) is the amount read. @param[in] eth Pointer to the relevant Ethernet data structure @param[out] buf Where to put the data @return The length if successful, zero if no packet was available, a negative value otherwise. */ /* -------------------------------------------------------------------------- */ static ssize_t eth_read_tap_packet (struct eth_device *eth, unsigned char *buf) { struct pollfd fds[1]; int n; ssize_t packet_length; /* Poll to see if there is data to read */ fds[0].fd = eth->rtx_fd; fds[0].events = POLLIN; n = poll (fds, 1, 0); if (n < 0) { fprintf (stderr, "Warning: Poll for TAP receive failed %s: ignored.\n", strerror (errno)); return -1; } else if ((n > 0) && ((fds[0].revents & POLLIN) == POLLIN)) { /* Data to be read from TAP */ packet_length = read (eth->rtx_fd, buf, ETH_MAXPL); #if ETH_DEBUG printf ("%d bytes read from TAP.\n", (int) packet_length); #endif if (packet_length < 0) { fprintf (stderr, "Warning: Read of RXTATE_RECV failed: %s.\n", strerror (errno)); SET_FLAG (eth->regs.int_source, ETH_INT_SOURCE, RXE); /* Signal interrupt if enabled, and no interrupt currently in progress. */ if (TEST_FLAG (eth->regs.int_mask, ETH_INT_MASK, RXE_M) && !eth->int_line_stat) { #if ETH_DEBUG printf ("Ethernet failed receive interrupt\n"); #endif report_interrupt (eth->mac_int); eth->int_line_stat = 1; } } return packet_length; } else { return 0; /* No packet */ } } /* eth_read_tap_packet () */ #endif /* -------------------------------------------------------------------------- */ /*!Read an Ethernet packet. This reads a single Ethernet packet from the outside world into the supplied buffer. It deals with the different types of external interface. @param[in] eth Pointer to the relevant Ethernet data structure @param[out] buf Where to put the data @return The length if successful, zero if no packet was available, a negative value otherwise. */ /* -------------------------------------------------------------------------- */ static ssize_t eth_read_packet (struct eth_device *eth, unsigned char *buf) { switch (eth->rtx_type) { case ETH_RTX_FILE: return eth_read_file_packet (eth, buf); #if HAVE_LINUX_IF_TUN_H==1 case ETH_RTX_TAP: return eth_read_tap_packet (eth, buf); #endif default: fprintf (stderr, "Unknown Ethernet read interface: ignored.\n"); return (ssize_t) -1; } } /* eth_read_packet () */ /* -------------------------------------------------------------------------- */ /*!Fill a buffer descriptor A buffer descriptor is empty. Attempt to fill it from the outside world. @param[in] eth The Ethernet data structure, passed as a void pointer. */ /* -------------------------------------------------------------------------- */ static void eth_fill_bd (struct eth_device *eth) { /* First word of BD is flags and length, second is pointer to buffer */ unsigned long int bd_info = eth->regs.bd_ram[eth->rx_bd_index]; unsigned long int bd_addr = eth->regs.bd_ram[eth->rx_bd_index + 1]; long int packet_length; long int bytes_read; unsigned char buf[ETH_MAXPL]; /* Clear various status bits */ CLEAR_FLAG (bd_info, ETH_RX_BD, MISS); CLEAR_FLAG (bd_info, ETH_RX_BD, INVALID); CLEAR_FLAG (bd_info, ETH_RX_BD, DRIBBLE); CLEAR_FLAG (bd_info, ETH_RX_BD, UVERRUN); CLEAR_FLAG (bd_info, ETH_RX_BD, COLLISION); CLEAR_FLAG (bd_info, ETH_RX_BD, TOOBIG); CLEAR_FLAG (bd_info, ETH_RX_BD, TOOSHORT); /* Loopback is permitted. We believe that Linux never uses it, so we'll note the attempt and ignore. @todo We should support this. */ if (TEST_FLAG (eth->regs.moder, ETH_MODER, LOOPBCK)) { PRINTF ("Ethernet loopback requested.\n"); fprintf (stderr, "ERROR: Loopback not supported. Ignored.\n"); } packet_length = eth_read_packet (eth, buf); if (packet_length <= 0) { /* Empty packet or error. No more to do here. */ return; } /* Got a packet successfully. If not promiscuous mode, check the destination address is meant for us. */ if (!TEST_FLAG (eth->regs.moder, ETH_MODER, PRO)) { if (TEST_FLAG (eth->regs.moder, ETH_MODER, IAM)) { /* There is little documentation of how IAM is supposed to work. It seems that some mapping function (not defined) maps the address down to a number in the range 0-63. If that bit is set in HASH0/HASH1 registers, the packet is accepted. */ fprintf (stderr, "Warning: Individual Address Mode ignored.\n"); } /* Check for HW address match. */ if ((0 != bcmp (eth->mac_address, buf, ETHER_ADDR_LEN)) && (0 != bcmp (mac_broadcast, buf, ETHER_ADDR_LEN))) { #if ETH_DEBUG printf ("packet for %.2x:%.2x:%.2x:%.2x:%.2x:%.2x ignored.\n", buf[0], buf[1], buf[2], buf[3], buf[4], buf[5]); #endif /* Not for us. No more to do here. */ return; } } /* Transfer the buffer into the BD. */ #if ETH_DEBUG printf ("writing to Rx BD%d: %d bytes @ 0x%.8x\n", (int) eth->rx_bd_index / 2, (int) packet_length, (unsigned int)bd_addr); #endif for (bytes_read = 0; bytes_read < packet_length; bytes_read +=4) { unsigned long int send_word = ((unsigned long) buf[bytes_read] << 24) | ((unsigned long) buf[bytes_read + 1] << 16) | ((unsigned long) buf[bytes_read + 2] << 8) | ((unsigned long) buf[bytes_read + 3] ); set_direct32 (bd_addr + bytes_read, send_word, 0, 0); } #if ETH_DEBUG printf("BD filled with 0x%08lx bytes.\n", bytes_read); #endif /* Write result to BD. The OpenRISC MAC hardware passes on the CRC (which it should not). The Linux drivers have been written to expect a value (which they ignore). So for consistency, we pretend the length is 4 bytes longer. This is now controlled by a configuration parameter, dummy_crc. For backwards compatibility, it defaults to TRUE. */ SET_FIELD (bd_info, ETH_RX_BD, LENGTH, packet_length + (eth->dummy_crc ? 4 : 0)); CLEAR_FLAG (bd_info, ETH_RX_BD, READY); SET_FLAG (eth->regs.int_source, ETH_INT_SOURCE, RXB); eth->regs.bd_ram[eth->rx_bd_index] = bd_info; /* Advance to next BD. The Rx BDs start after the Tx BDs. */ if (TEST_FLAG (bd_info, ETH_RX_BD, WRAP) || (eth->rx_bd_index >= ETH_BD_COUNT)) { eth->rx_bd_index = eth->regs.tx_bd_num * 2; } else { eth->rx_bd_index += 2; } /* Raise an interrupt if necessary. */ if (TEST_FLAG (eth->regs.int_mask, ETH_INT_MASK, RXB_M) && TEST_FLAG (bd_info, ETH_RX_BD, IRQ)) { if (eth->int_line_stat) { fprintf (stderr, "Warning: Interrupt active during Rx.\n"); } else { #if ETH_DEBUG printf ("Rx successful receive interrupt\n"); #endif report_interrupt (eth->mac_int); eth->int_line_stat = 1; } } } /* eth_fill_bd () */ /* -------------------------------------------------------------------------- */ /*!Ignore a packet from the TAP interface. We don't have a BD ready, so any packets waiting should be thrown away. @param[in] eth The Ethernet data structure. @return 1 (TRUE) if more or more packets were discarded, zero otherwise. */ /* -------------------------------------------------------------------------- */ static int eth_ignore_tap_packets (struct eth_device *eth) { int result = 0; #if HAVE_LINUX_IF_TUN_H==1 int n; /* Read packets until there are none left. */ do { struct pollfd fds[1]; /* Poll to see if there is anything to be read. */ fds[0].fd = eth->rtx_fd; fds[0].events = POLLIN; n = poll (fds, 1, 0); if (n < 0) { /* Give up with a warning if poll fails */ fprintf (stderr, "Warning: Poll error while emptying TAP: %s: ignored.\n", strerror (errno)); return result; } else if ((n > 0) && ((fds[0].revents & POLLIN) == POLLIN)) { unsigned char buf[ETH_MAXPL]; ssize_t nread = eth_read_packet (eth, buf); if (nread < 0) { /* Give up with a warning if read fails */ fprintf (stderr, "Warning: Read of when Ethernet busy failed %s.\n", strerror (errno)); return result; } else if (nread > 0) { /* Record that a packet was thrown away. */ result = 1; #if ETH_DEBUG printf ("Ethernet discarding %d bytes from TAP while BD full.\n", nread); #endif } } } while (n > 0); #endif return result; } /* eth_ignore_tap_packets () */ /* -------------------------------------------------------------------------- */ /*!Rx clock function. Responsible for starting and completing any RX actions. The original version had 4 states, which allowed modeling the transfer of data one byte per cycle. For now we use only the one state for efficiency. When the buffer is empty, we fill it from the external world. We schedule to wake up again each cycle. This means we will get called when the core is still processing the previous interrupt. To avoid races, we do nothing until the interrupt is cleared. @todo We should eventually reinstate the one byte per cycle transfer. @param[in] dat The Ethernet data structure, passed as a void pointer. */ /* -------------------------------------------------------------------------- */ static void eth_controller_rx_clock (void *dat) { struct eth_device *eth = dat; /* Only do anything if there is not an interrupt outstanding. */ if (!eth->int_line_stat) { /* First word of the BD is flags, where we can test if it's ready. */ if (TEST_FLAG (eth->regs.bd_ram[eth->rx_bd_index], ETH_RX_BD, READY)) { /* The BD is empty, so we try to fill it with data from the outside world. */ eth_fill_bd (eth); /* BD ready to be filled. */ } else if ((TEST_FLAG (eth->regs.moder, ETH_MODER, RXEN)) && (ETH_RTX_FILE == eth->rtx_type)) { /* The BD is full, Rx is enabled and we are reading from an external TAP interface. We can't take any more, so we'll throw oustanding input packets on the floor. @note We don't do this for file I/O, since it would discard everything immediately! */ if (eth_ignore_tap_packets (eth)) { /* A packet has been thrown away, so mark the INT_SOURCE register accordingly. */ SET_FLAG (eth->regs.int_source, ETH_INT_SOURCE, BUSY); /* Raise an interrupt if necessary. */ if (TEST_FLAG (eth->regs.int_mask, ETH_INT_MASK, BUSY_M)) { if (eth->int_line_stat) { fprintf (stderr, "Warning: Interrupt active during ignore.\n"); } else { #if ETH_DEBUG printf ("Ethernet Rx BUSY interrupt\n"); #endif report_interrupt (eth->mac_int); eth->int_line_stat = 1; } } } } } /* Whatever happens, we reschedule a wake up in the future. */ SCHED_ADD (eth_controller_rx_clock, dat, RTX_RESCHED_PERIOD); } /* eth_controller_rx_clock () */ /* -------------------------------------------------------------------------- */ /*!VAPI connection to outside. Used for remote testing of the interface. Currently does nothing. @param[in] id The VAPI ID to use. @param[in] data Any data associated (unused here). @param[in] dat The Ethernet data structure, cast to a void pointer. */ /* -------------------------------------------------------------------------- */ static void eth_vapi_read (unsigned long int id, unsigned long int data, void *dat) { unsigned long int 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; } } /* -------------------------------------------------------------------------- */ /*!Print register values on stdout @param[in] dat The Ethernet interface data structure. */ /* -------------------------------------------------------------------------- */ 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[5], eth->mac_address[4], eth->mac_address[3], eth->mac_address[2], eth->mac_address[1], eth->mac_address[0]); PRINTF ("HASH0 : 0x%08lX\n", eth->regs.hash0); PRINTF ("HASH1 : 0x%08lX\n", eth->regs.hash1); } /* eth_status () */ /* -------------------------------------------------------------------------- */ /*!Open the external file interface to the Ethernet The data is represented by an input and an output file. @param[in] eth The Ethernet interface data structure. */ /* -------------------------------------------------------------------------- */ static void eth_open_file_if (struct eth_device *eth) { /* (Re-)open TX/RX files */ if (eth->rxfd >= 0) { close (eth->rxfd); } if (eth->txfd >= 0) { close (eth->txfd); } eth->rxfd = -1; eth->txfd = -1; eth->rxfd = open (eth->rxfile, O_RDONLY); if (eth->rxfd < 0) { fprintf (stderr, "Warning: Cannot open Ethernet RX file \"%s\": %s\n", eth->rxfile, strerror (errno)); } eth->txfd = open (eth->txfile, #if defined(O_SYNC) /* BSD/MacOS X doesn't know about O_SYNC */ O_SYNC | #endif O_RDWR | O_CREAT | O_APPEND, S_IRUSR | S_IWUSR | S_IRGRP | S_IROTH); if (eth->txfd < 0) { fprintf (stderr, "Warning: Cannot open Ethernet TX file \"%s\": %s\n", eth->txfile, strerror (errno)); } } /* eth_open_file_if () */ #if HAVE_LINUX_IF_TUN_H==1 /* -------------------------------------------------------------------------- */ /*!Open the external TAP interface to the Ethernet Packets are transferred over a TAP/TUN interface. We assume a persistent tap interface has been set up and is owned by the user, so they can open and manipulate it. See the User Guide for details of setting this up. @todo We don't flush the TAP interface. Should we? @param[in] eth The Ethernet interface data structure. */ /* -------------------------------------------------------------------------- */ static void eth_open_tap_if (struct eth_device *eth) { struct ifreq ifr; /* We don't support re-opening. If it's open, it stays open. */ if (eth->rtx_fd >= 0) { return; } /* Open the TUN/TAP device */ eth->rtx_fd = open ("/dev/net/tun", O_RDWR); if( eth->rtx_fd < 0 ) { fprintf (stderr, "Warning: Failed to open TUN/TAP device: %s\n", strerror (errno)); eth->rtx_fd = -1; return; } /* Turn it into a specific TAP device. If we haven't specified a specific (persistent) device, one will be created, but that requires superuser, or at least CAP_NET_ADMIN capabilities. */ memset (&ifr, 0, sizeof(ifr)); ifr.ifr_flags = IFF_TAP | IFF_NO_PI; strncpy (ifr.ifr_name, eth->tap_dev, IFNAMSIZ); if (ioctl (eth->rtx_fd, TUNSETIFF, (void *) &ifr) < 0) { fprintf (stderr, "Warning: Failed to set TAP device %s: %s\n", eth->tap_dev, strerror (errno)); close (eth->rtx_fd); eth->rtx_fd = -1; return; } #if ETH_DEBUG PRINTF ("Opened TAP %s\n", ifr.ifr_name); #endif } /* eth_open_tap_if () */ #endif /* -------------------------------------------------------------------------- */ /*!Open the external interface to the Ethernet Calls the appropriate function for the interface type. @param[in] eth The Ethernet interface data structure. */ /* -------------------------------------------------------------------------- */ static void eth_open_if (struct eth_device *eth) { switch (eth->rtx_type) { case ETH_RTX_FILE: eth_open_file_if (eth); break; #if HAVE_LINUX_IF_TUN_H==1 case ETH_RTX_TAP: eth_open_tap_if (eth); break; #endif default: fprintf (stderr, "Unknown Ethernet interface: ignored.\n"); break; } } /* eth_open_if () */ /* -------------------------------------------------------------------------- */ /*!Reset the Ethernet. Open the correct type of simulation interface to the outside world. Initialize all registers to default and places devices in memory address space. @param[in] dat The Ethernet interface data structure. */ /* -------------------------------------------------------------------------- */ static void eth_reset (void *dat) { struct eth_device *eth = dat; #if ETH_DEBUG printf ("Resetting Ethernet\n"); #endif /* Nothing to do if we do not have a base address set, or we are not enabled. */ if (!eth->enabled || (0 == eth->baseaddr)) { return; } eth_open_if (eth); /* Set registers to default values */ memset (&(eth->regs), 0, sizeof (eth->regs)); eth->regs.moder = 0x0000A000; /* Padding & CRC enabled */ eth->regs.ipgt = 0x00000012; /* Half duplex (matches MODER) */ eth->regs.ipgr1 = 0x0000000C; /* Recommended value */ eth->regs.ipgr2 = 0x00000012; /* Recommended value */ eth->regs.packetlen = 0x003C0600; /* MINFL 60, MAXFL 1,536 bytes */ eth->regs.collconf = 0x000F003F; /* MAXRET 15, COLLVALID 63 */ eth->regs.tx_bd_num = 0x00000040; /* Max Tx BD */ eth->regs.miimoder = 0x00000064; /* Send preamble, CLKDIV 100 */ /* Reset TX/RX BD indexes. The Rx BD indexes start after the Tx BD indexes. */ eth->tx_bd_index = 0; eth->rx_bd_index = eth->regs.tx_bd_num * 2; /* Reset IRQ line status */ eth->int_line_stat = 0; /* Initialize VAPI */ if (eth->base_vapi_id) { vapi_install_multi_handler (eth->base_vapi_id, ETH_NUM_VAPI_IDS, eth_vapi_read, dat); } } /* eth_reset () */ #if ETH_DEBUG /* -------------------------------------------------------------------------- */ /*!Map a register address to its name @param[in[ addr The address of the register to name (offset from base). @return The name of the register. */ /* -------------------------------------------------------------------------- */ static char * eth_regname (oraddr_t addr) { static char bdstr[8]; /* For "BD[nnn]" */ switch (addr) { case ETH_MODER: return "MODER"; case ETH_INT_SOURCE: return "INT_SOURCE"; case ETH_INT_MASK: return "INT_MASK"; case ETH_IPGT: return "IPGT"; case ETH_IPGR1: return "IPGR1"; case ETH_IPGR2: return "IPGR2"; case ETH_PACKETLEN: return "PACKETLEN"; case ETH_COLLCONF: return "COLLCONF"; case ETH_TX_BD_NUM: return "TX_BD_NUM"; case ETH_CTRLMODER: return "CTRLMODER"; case ETH_MIIMODER: return "MIIMODER"; case ETH_MIICOMMAND: return "MIICOMMAND"; case ETH_MIIADDRESS: return "MIIADDRESS"; case ETH_MIITX_DATA: return "MIITX_DATA"; case ETH_MIIRX_DATA: return "MIIRX_DATA"; case ETH_MIISTATUS: return "MIISTATUS"; case ETH_MAC_ADDR0: return "MAC_ADDR0"; case ETH_MAC_ADDR1: return "MAC_ADDR1"; case ETH_HASH0: return "HASH0"; case ETH_HASH1: return "HASH1"; default: /* Buffer descriptors are a special case. */ if ((addr >= ETH_BD_BASE) && (addr < ETH_BD_BASE + ETH_BD_SPACE)) { sprintf (bdstr, "BD[%.3d]", (addr - ETH_BD_BASE) / 4); return bdstr; } else { return "INVALID"; } } } /* eth_regname () */ #endif /* -------------------------------------------------------------------------- */ /*!Read a register @param[in] addr The address of the register to read (offset from base). @param[in] dat The Ethernet interface data structure, cast to a void pointer. @return The value read. */ /* -------------------------------------------------------------------------- */ static uint32_t eth_read32 (oraddr_t addr, void *dat) { struct eth_device *eth = dat; uint32_t res; switch (addr) { case ETH_MODER: res = eth->regs.moder; break; case ETH_INT_SOURCE: res = eth->regs.int_source; break; case ETH_INT_MASK: res = eth->regs.int_mask; break; case ETH_IPGT: res = eth->regs.ipgt; break; case ETH_IPGR1: res = eth->regs.ipgr1; break; case ETH_IPGR2: res = eth->regs.ipgr2; break; case ETH_PACKETLEN: res = eth->regs.packetlen; break; case ETH_COLLCONF: res = eth->regs.collconf; break; case ETH_TX_BD_NUM: res = eth->regs.tx_bd_num; break; case ETH_CTRLMODER: res = eth->regs.controlmoder; break; case ETH_MIIMODER: res = eth->regs.miimoder; break; case ETH_MIICOMMAND: res = eth->regs.miicommand; break; case ETH_MIIADDRESS: res = eth->regs.miiaddress; break; case ETH_MIITX_DATA: res = eth->regs.miitx_data; break; case ETH_MIIRX_DATA: res = eth->regs.miirx_data; break; case ETH_MIISTATUS: res = eth->regs.miistatus; break; case ETH_MAC_ADDR0: res = (((unsigned long) eth->mac_address[2]) << 24) | (((unsigned long) eth->mac_address[3]) << 16) | (((unsigned long) eth->mac_address[4]) << 8) | (unsigned long) eth->mac_address[5]; break; case ETH_MAC_ADDR1: res = (((unsigned long) eth->mac_address[0]) << 8) | (unsigned long) eth->mac_address[1]; break; case ETH_HASH0: res = eth->regs.hash0; break; case ETH_HASH1: res = eth->regs.hash1; break; default: /* Buffer descriptors are a special case. */ if ((addr >= ETH_BD_BASE) && (addr < ETH_BD_BASE + ETH_BD_SPACE)) { res = eth->regs.bd_ram[(addr - ETH_BD_BASE) / 4]; break; } else { fprintf (stderr, "Warning: eth_read32( 0x%" PRIxADDR " ): Illegal address\n", addr + eth->baseaddr); res = 0; } } #if ETH_DEBUG /* Only trace registers of particular interest */ switch (addr) { case ETH_MODER: case ETH_INT_SOURCE: case ETH_INT_MASK: case ETH_IPGT: case ETH_IPGR1: case ETH_IPGR2: case ETH_PACKETLEN: case ETH_COLLCONF: case ETH_TX_BD_NUM: case ETH_CTRLMODER: case ETH_MAC_ADDR0: case ETH_MAC_ADDR1: printf ("eth_read32: %s = 0x%08lx\n", eth_regname (addr), (unsigned long int) res); } #endif return res; } /* eth_read32 () */ /* -------------------------------------------------------------------------- */ /*!Emulate MIIM transaction to ethernet PHY @param[in] eth Ethernet device datastruture. */ /* -------------------------------------------------------------------------- */ static void eth_miim_trans (struct eth_device *eth) { 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)): /*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 = ADVERTISE_FULL; 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; } } /* eth_miim_trans () */ /* -------------------------------------------------------------------------- */ /*!Write a register @note Earlier versions of this code treated ETH_INT_SOURCE as an "interrupt pending" register and reissued interrupts if ETH_INT_MASK was changed, enabling an interrupt that had previously been cleared. This led to spurious double interrupt. In the present version, the only way an interrupt can be generated is at the time ETH_INT_SOURCE is set in the Tx/Rx controllers and the only way an interrupt can be cleared is by writing to ETH_INT_SOURCE. @param[in] addr The address of the register to read (offset from base). @param[in] value The value to write. @param[in] dat The Ethernet interface data structure, cast to a void pointer. */ /* -------------------------------------------------------------------------- */ static void eth_write32 (oraddr_t addr, uint32_t value, void *dat) { struct eth_device *eth = dat; #if ETH_DEBUG /* Only trace registers of particular interest */ switch (addr) { case ETH_MODER: case ETH_INT_SOURCE: case ETH_INT_MASK: case ETH_IPGT: case ETH_IPGR1: case ETH_IPGR2: case ETH_PACKETLEN: case ETH_COLLCONF: case ETH_TX_BD_NUM: case ETH_CTRLMODER: case ETH_MAC_ADDR0: case ETH_MAC_ADDR1: printf ("eth_write32: 0x%08lx to %s ", (unsigned long int) value, eth_regname (addr)); } /* Detail register transitions on MODER, INT_SOURCE AND INT_MASK */ switch (addr) { case ETH_MODER: printf (" 0x%08lx -> ", (unsigned long) eth->regs.moder); break; case ETH_INT_SOURCE: printf (" 0x%08lx -> ", (unsigned long) eth->regs.int_source); break; case ETH_INT_MASK: printf (" 0x%08lx -> ", (unsigned long) eth->regs.int_mask); break; } #endif switch (addr) { case ETH_MODER: if (!TEST_FLAG (eth->regs.moder, ETH_MODER, RXEN) && TEST_FLAG (value, ETH_MODER, RXEN)) { /* Enabling receive, flush any oustanding input (TAP only), reset the BDs and schedule the Rx controller on the next clock cycle. */ if (ETH_RTX_TAP == eth->rtx_type) { (void) eth_ignore_tap_packets (eth); } eth->rx_bd_index = eth->regs.tx_bd_num * 2; SCHED_ADD (eth_controller_rx_clock, dat, 1); } else if (!TEST_FLAG (value, ETH_MODER, RXEN) && TEST_FLAG (eth->regs.moder, ETH_MODER, RXEN)) { /* Disabling Rx, so stop scheduling the Rx controller. */ SCHED_FIND_REMOVE (eth_controller_rx_clock, dat); } if (!TEST_FLAG (eth->regs.moder, ETH_MODER, TXEN) && TEST_FLAG (value, ETH_MODER, TXEN)) { /* Enabling transmit, reset the BD and schedule the Tx controller on the next clock cycle. */ eth->tx_bd_index = 0; SCHED_ADD (eth_controller_tx_clock, dat, 1); } else if (!TEST_FLAG (value, ETH_MODER, TXEN) && TEST_FLAG (eth->regs.moder, ETH_MODER, TXEN)) { /* Disabling Tx, so stop scheduling the Tx controller. */ SCHED_FIND_REMOVE (eth_controller_tx_clock, dat); } /* Reset the interface if so requested. */ if (TEST_FLAG (value, ETH_MODER, RST)) { eth_reset (dat); } eth->regs.moder = value; /* Update the register */ break; case ETH_INT_SOURCE: eth->regs.int_source &= ~value; /* Clear IRQ line if all interrupt sources have been dealt with @todo Is this really right? */ if (!(eth->regs.int_source & eth->regs.int_mask) && eth->int_line_stat) { clear_interrupt (eth->mac_int); eth->int_line_stat = 0; } break; case ETH_INT_MASK: eth->regs.int_mask = value; /* The old code would report an interrupt if we enabled an interrupt when if we enabled interrupts and the core was not currently processing an interrupt, and there was an interrupt pending. However this led (at least on some machines) to orphaned interrupts in the device driver. So in this version of the code we do not report interrupts on a mask change. This is not apparently consistent with the Verilog, but it does mean that the orphaned interrupts problem does not occur, and has no apparent effect on Ethernet performance. More investigation is needed to determine if this is a bug in Or1ksim interrupt handling, or a bug in the device driver, which does not manifest with real HW. Otherwise clear down the interrupt. @todo Is this really right. */ if ((eth->regs.int_source & eth->regs.int_mask) && !eth->int_line_stat) { #if ETH_DEBUG printf ("ETH_MASK changed with apparent pending interrupt.\n"); #endif } else if (eth->int_line_stat) { clear_interrupt (eth->mac_int); eth->int_line_stat = 0; } break; case ETH_IPGT: eth->regs.ipgt = value; break; case ETH_IPGR1: eth->regs.ipgr1 = value; break; case ETH_IPGR2: eth->regs.ipgr2 = value; break; case ETH_PACKETLEN: eth->regs.packetlen = value; break; case ETH_COLLCONF: eth->regs.collconf = value; break; case ETH_TX_BD_NUM: /* When TX_BD_NUM is written, also reset current RX BD index */ eth->regs.tx_bd_num = value & 0xFF; eth->rx_bd_index = eth->regs.tx_bd_num * 2; break; case ETH_CTRLMODER: eth->regs.controlmoder = value; break; case ETH_MIIMODER: eth->regs.miimoder = value; break; case ETH_MIICOMMAND: eth->regs.miicommand = value; /* Perform MIIM transaction, if required */ eth_miim_trans (eth); break; case ETH_MIIADDRESS: eth->regs.miiaddress = value; break; case ETH_MIITX_DATA: eth->regs.miitx_data = value; break; case ETH_MIIRX_DATA: /* Register is R/O */ break; case ETH_MIISTATUS: /* Register is R/O */ break; case ETH_MAC_ADDR0: eth->mac_address[5] = value & 0xFF; eth->mac_address[4] = (value >> 8) & 0xFF; eth->mac_address[3] = (value >> 16) & 0xFF; eth->mac_address[2] = (value >> 24) & 0xFF; break; case ETH_MAC_ADDR1: eth->mac_address[1] = value & 0xFF; eth->mac_address[0] = (value >> 8) & 0xFF; break; case ETH_HASH0: eth->regs.hash0 = value; break; case ETH_HASH1: eth->regs.hash1 = value; break; default: if ((addr >= ETH_BD_BASE) && (addr < ETH_BD_BASE + ETH_BD_SPACE)) { eth->regs.bd_ram[(addr - ETH_BD_BASE) / 4] = value; } else { fprintf (stderr, "Warning: eth_write32( 0x%" PRIxADDR " ): Illegal address\n", addr + eth->baseaddr); } break; } #if ETH_DEBUG switch (addr) { case ETH_MODER: printf ("0x%08lx\n", (unsigned long) eth->regs.moder); break; case ETH_INT_SOURCE: printf ("0x%08lx\n", (unsigned long) eth->regs.int_source); break; case ETH_INT_MASK: printf ("0x%08lx\n", (unsigned long) eth->regs.int_mask); break; case ETH_IPGT: case ETH_IPGR1: case ETH_IPGR2: case ETH_PACKETLEN: case ETH_COLLCONF: case ETH_TX_BD_NUM: case ETH_CTRLMODER: case ETH_MAC_ADDR0: case ETH_MAC_ADDR1: printf("\n"); break; } #endif } /* eth_write32 () */ /*---------------------------------------------------------------------------*/ /*!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 tap. @param[in] val The value to use. Currently "file" and "tap" are supported. @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_rtx_type (union param_val val, void *dat) { struct eth_device *eth = dat; if (0 == strcasecmp ("file", val.str_val)) { printf ("Ethernet FILE type\n"); eth->rtx_type = ETH_RTX_FILE; } #if HAVE_LINUX_IF_TUN_H==1 else if (0 == strcasecmp ("tap", val.str_val)) { printf ("Ethernet TAP type\n"); eth->rtx_type = ETH_RTX_TAP; } #endif else { fprintf (stderr, "Warning: Unknown Ethernet type: file assumed.\n"); eth->rtx_type = ETH_RTX_FILE; } } /* 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 TAP device. If we are not superuser (or do not have CAP_NET_ADMIN priviledges), then we must work with a persistent TAP device that is already set up. This option specifies the device to user. @param[in] val The value to use. @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_tap_dev (union param_val val, void *dat) { struct eth_device *eth = dat; if (NULL != eth->tap_dev) { free (eth->tap_dev); eth->tap_dev = NULL; } eth->tap_dev = strdup (val.str_val); if (NULL == eth->tap_dev) { fprintf (stderr, "ERROR: Peripheral Ethernet: Run out of memory\n"); exit (-1); } } /* eth_tap_dev() */ /*---------------------------------------------------------------------------*/ /*!Set the PHY address Used to identify different physical interfaces (important for MII). @param[in] val The value to use. @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ 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; } /* eth_phy_addr () */ /*---------------------------------------------------------------------------*/ /*!Enable or disable a dummy CRC The MAC should not report anything about the CRC back to the core. However the hardware implementation of the OpenRISC MAC does, and the Linux drivers have been written to expect the value (which they ignore). Setting this parameter causes a dummy CRC to be added. For consistency with the hardware, its default setting is TRUE. @param[in] val The value to use @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_dummy_crc (union param_val val, void *dat) { struct eth_device *eth = dat; eth->dummy_crc = val.int_val; } /* eth_dummy_crc() */ /*---------------------------------------------------------------------------*/ /*!Set the VAPI id Used for remote testing of the interface. @param[in] val The value to use. @param[in] dat The config data structure */ /*---------------------------------------------------------------------------*/ static void eth_vapi_id (union param_val val, void *dat) { struct eth_device *eth = dat; eth->base_vapi_id = val.int_val; } /* eth_vapi_id () */ /*---------------------------------------------------------------------------*/ /*!Start the initialization of 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->int_line_stat= 0; new->rtx_type = ETH_RTX_FILE; new->rx_channel = 0; new->tx_channel = 0; new->rtx_fd = -1; new->rxfile = strdup ("eth_rx"); new->txfile = strdup ("eth_tx"); new->tap_dev = strdup (""); new->phy_addr = 0; new->dummy_crc = 1; new->base_vapi_id = 0; return new; } /* eth_sec_start () */ /*---------------------------------------------------------------------------*/ /*!Complete the initialization of a new Ethernet configuration ALL parameters are set explicitly to default values. */ /*---------------------------------------------------------------------------*/ 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->tap_dev); 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); } /* eth_sec_end () */ /*---------------------------------------------------------------------------*/ /*!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_STR, 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, "tap_dev", PARAMT_STR, eth_tap_dev); reg_config_param (sec, "phy_addr", PARAMT_INT, eth_phy_addr); reg_config_param (sec, "dummy_crc", PARAMT_INT, eth_dummy_crc); reg_config_param (sec, "vapi_id", PARAMT_INT, eth_vapi_id); } /* reg_ethernet_sec() */
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