/* Copyright holders: Peter Grehan, SA1988, Tenshi see COPYING for more details */ /* $Id: ne2k.cc,v 1.56.2.1 2004/02/02 22:37:22 cbothamy Exp $ */ /* Copyright (C) 2002 MandrakeSoft S.A. MandrakeSoft S.A. 43, rue d'Aboukir 75002 Paris - France http://www.linux-mandrake.com/ http://www.mandrakesoft.com/ */ /* Peter Grehan (grehan@iprg.nokia.com) coded all of this NE2000/ether stuff. */ #include #include #include #include #include #include #include "slirp/slirp.h" #include "slirp/queue.h" #include "ibm.h" #include "io.h" #include "mem.h" #include "rom.h" #include "pci.h" #include "pic.h" #include "timer.h" #include "device.h" #include "config.h" #include "disc_random.h" #include "network.h" #include "net_ne2000.h" /* THIS IS THE DEFAULT MAC ADDRESS .... so it wont place nice with multiple VMs. YET. */ uint8_t maclocal[6] = {0xac, 0xde, 0x48, 0x88, 0xbb, 0xaa}; uint8_t maclocal_pci[6] = {0xac, 0xde, 0x48, 0x88, 0xbb, 0xaa}; #define NETBLOCKING 0 /* we won't block our pcap */ pcap_t *net_pcap; queueADT slirpq; int net_slirp_inited=0; int net_is_pcap=0; /* and pretend pcap is dead. */ int fizz=0; void slirp_tic(); #define BX_RESET_HARDWARE 0 #define BX_RESET_SOFTWARE 1 /* Never completely fill the ne2k ring so that we never hit the unclear completely full buffer condition. */ #define BX_NE2K_NEVER_FULL_RING (1) #define BX_NE2K_MEMSIZ (32*1024) #define BX_NE2K_MEMSTART (16*1024) #define BX_NE2K_MEMEND (BX_NE2K_MEMSTART + BX_NE2K_MEMSIZ) uint8_t rtl8029as_eeprom[128]; typedef struct ne2000_t { /* ne2k register state */ /* Page 0 */ /* Command Register - 00h read/write */ struct CR_t { int stop; /* STP - Software Reset command */ int start; /* START - start the NIC */ int tx_packet; /* TXP - initiate packet transmission */ uint8_t rdma_cmd; /* RD0,RD1,RD2 - Remote DMA command */ uint8_t pgsel; /* PS0,PS1 - Page select */ } CR; /* Interrupt Status Register - 07h read/write */ struct ISR_t { int pkt_rx; /* PRX - packet received with no errors */ int pkt_tx; /* PTX - packet transmitted with no errors */ int rx_err; /* RXE - packet received with 1 or more errors */ int tx_err; /* TXE - packet tx'd " " " " " */ int overwrite; /* OVW - rx buffer resources exhausted */ int cnt_oflow; /* CNT - network tally counter MSB's set */ int rdma_done; /* RDC - remote DMA complete */ int reset; /* RST - reset status */ } ISR; /* Interrupt Mask Register - 0fh write */ struct IMR_t { int rx_inte; /* PRXE - packet rx interrupt enable */ int tx_inte; /* PTXE - packet tx interrput enable */ int rxerr_inte; /* RXEE - rx error interrupt enable */ int txerr_inte; /* TXEE - tx error interrupt enable */ int overw_inte; /* OVWE - overwrite warn int enable */ int cofl_inte; /* CNTE - counter o'flow int enable */ int rdma_inte; /* RDCE - remote DMA complete int enable */ int reserved; /* D7 - reserved */ } IMR; /* Data Configuration Register - 0eh write */ struct DCR_t { int wdsize; /* WTS - 8/16-bit select */ int endian; /* BOS - byte-order select */ int longaddr; /* LAS - long-address select */ int loop; /* LS - loopback select */ int auto_rx; /* AR - auto-remove rx packets with remote DMA */ uint8_t fifo_size; /* FT0,FT1 - fifo threshold */ } DCR; /* Transmit Configuration Register - 0dh write */ struct TCR_t { int crc_disable; /* CRC - inhibit tx CRC */ uint8_t loop_cntl; /* LB0,LB1 - loopback control */ int ext_stoptx; /* ATD - allow tx disable by external mcast */ int coll_prio; /* OFST - backoff algorithm select */ uint8_t reserved; /* D5,D6,D7 - reserved */ } TCR; /* Transmit Status Register - 04h read */ struct TSR_t { int tx_ok; /* PTX - tx complete without error */ int reserved; /* D1 - reserved */ int collided; /* COL - tx collided >= 1 times */ int aborted; /* ABT - aborted due to excessive collisions */ int no_carrier; /* CRS - carrier-sense lost */ int fifo_ur; /* FU - FIFO underrun */ int cd_hbeat; /* CDH - no tx cd-heartbeat from transceiver */ int ow_coll; /* OWC - out-of-window collision */ } TSR; /* Receive Configuration Register - 0ch write */ struct RCR_t { int errors_ok; /* SEP - accept pkts with rx errors */ int runts_ok; /* AR - accept < 64-byte runts */ int broadcast; /* AB - accept eth broadcast address */ int multicast; /* AM - check mcast hash array */ int promisc; /* PRO - accept all packets */ int monitor; /* MON - check pkts, but don't rx */ uint8_t reserved; /* D6,D7 - reserved */ } RCR; /* Receive Status Register - 0ch read */ struct RSR_t { int rx_ok; /* PRX - rx complete without error */ int bad_crc; /* CRC - Bad CRC detected */ int bad_falign; /* FAE - frame alignment error */ int fifo_or; /* FO - FIFO overrun */ int rx_missed; /* MPA - missed packet error */ int rx_mbit; /* PHY - unicast or mcast/bcast address match */ int rx_disabled; /* DIS - set when in monitor mode */ int deferred; /* DFR - collision active */ } RSR; uint16_t local_dma; /* 01,02h read ; current local DMA addr */ uint8_t page_start; /* 01h write ; page start register */ uint8_t page_stop; /* 02h write ; page stop register */ uint8_t bound_ptr; /* 03h read/write ; boundary pointer */ uint8_t tx_page_start; /* 04h write ; transmit page start register */ uint8_t num_coll; /* 05h read ; number-of-collisions register */ uint16_t tx_bytes; /* 05,06h write ; transmit byte-count register */ uint8_t fifo; /* 06h read ; FIFO */ uint16_t remote_dma; /* 08,09h read ; current remote DMA addr */ uint16_t remote_start; /* 08,09h write ; remote start address register */ uint16_t remote_bytes; /* 0a,0bh write ; remote byte-count register */ uint8_t tallycnt_0; /* 0dh read ; tally counter 0 (frame align errors) */ uint8_t tallycnt_1; /* 0eh read ; tally counter 1 (CRC errors) */ uint8_t tallycnt_2; /* 0fh read ; tally counter 2 (missed pkt errors) */ /* Page 1 */ /* Command Register 00h (repeated) */ uint8_t physaddr[6]; /* 01-06h read/write ; MAC address */ uint8_t curr_page; /* 07h read/write ; current page register */ uint8_t mchash[8]; /* 08-0fh read/write ; multicast hash array */ /* Page 2 - diagnostic use only */ /* Command Register 00h (repeated) */ /* Page Start Register 01h read (repeated) Page Stop Register 02h read (repeated) Current Local DMA Address 01,02h write (repeated) Transmit Page start address 04h read (repeated) Receive Configuration Register 0ch read (repeated) Transmit Configuration Register 0dh read (repeated) Data Configuration Register 0eh read (repeated) Interrupt Mask Register 0fh read (repeated) */ uint8_t rempkt_ptr; /* 03h read/write ; remote next-packet pointer */ uint8_t localpkt_ptr; /* 05h read/write ; local next-packet pointer */ uint16_t address_cnt; /* 06,07h read/write ; address counter */ /* Page 3 - should never be modified. */ /* Novell ASIC state */ uint8_t macaddr[32]; /* ASIC ROM'd MAC address, even bytes */ uint8_t mem[BX_NE2K_MEMSIZ]; /* on-chip packet memory */ /* ne2k internal state */ uint32_t base_address; int base_irq; int tx_timer_index; int tx_timer_active; rom_t bios_rom; } ne2000_t; int disable_netbios = 0; void ne2000_tx_event(void *p, uint32_t val); uint32_t ne2000_chipmem_read(ne2000_t *ne2000, uint32_t address, unsigned int io_len); void ne2000_page0_write(ne2000_t *ne2000, uint32_t offset, uint32_t value, unsigned io_len); void ne2000_rx_frame(void *p, const void *buf, int io_len); #ifdef WALTJE #define ENABLE_NE2000_LOG int ne2000_do_log = 1; #else int ne2000_do_log = 0; #endif void ne2000_log(const char *format, ...) { #ifdef ENABLE_NE2000_LOG if (ne2000_do_log) { va_list ap; va_start(ap, format); vprintf(format, ap); va_end(ap); fflush(stdout); } #endif } static void ne2000_mac(uint8_t *mac) { if (network_card_current == 2) { memcpy(mac, maclocal_pci, 6); } else { memcpy(mac, maclocal, 6); } } void ne2000_generate_maclocal(uint32_t mac) { maclocal[0] = 0x00; /* 00:00:D8 (NE2000 ISA vendor prefix). */ maclocal[1] = 0x00; maclocal[2] = 0xD8; if (mac & 0xff000000) { /* Generating new MAC. */ maclocal[3] = disc_random_generate(); maclocal[4] = disc_random_generate(); maclocal[5] = disc_random_generate(); } else { maclocal[3] = (mac >> 16) & 0xff; maclocal[4] = (mac >> 8) & 0xff; maclocal[5] = mac & 0xff; } } void ne2000_generate_maclocal_pci(uint32_t mac) { maclocal_pci[0] = 0x00; /* 00:20:18 (RTL 8029AS PCI vendor prefix). */ maclocal_pci[1] = 0x20; maclocal_pci[2] = 0x18; if (mac & 0xff000000) { /* Generating new MAC. */ maclocal_pci[3] = disc_random_generate(); maclocal_pci[4] = disc_random_generate(); maclocal_pci[5] = disc_random_generate(); } else { maclocal_pci[3] = (mac >> 16) & 0xff; maclocal_pci[4] = (mac >> 8) & 0xff; maclocal_pci[5] = mac & 0xff; } } uint32_t net2000_get_maclocal() { uint32_t temp; temp = (((int) maclocal[3]) << 16); temp |= (((int) maclocal[4]) << 8); temp |= ((int) maclocal[5]); return temp; } uint32_t net2000_get_maclocal_pci() { uint32_t temp; temp = (((int) maclocal_pci[3]) << 16); temp |= (((int) maclocal_pci[4]) << 8); temp |= ((int) maclocal_pci[5]); return temp; } static void ne2000_setirq(ne2000_t *ne2000, int irq) { ne2000->base_irq = irq; } /* reset - restore state to power-up, cancelling all i/o */ static void ne2000_reset(void *p, int reset) { ne2000_t *ne2000 = (ne2000_t *)p; int i; ne2000_log("ne2000 reset\n"); /* Initialise the mac address area by doubling the physical address */ ne2000->macaddr[0] = ne2000->physaddr[0]; ne2000->macaddr[1] = ne2000->physaddr[0]; ne2000->macaddr[2] = ne2000->physaddr[1]; ne2000->macaddr[3] = ne2000->physaddr[1]; ne2000->macaddr[4] = ne2000->physaddr[2]; ne2000->macaddr[5] = ne2000->physaddr[2]; ne2000->macaddr[6] = ne2000->physaddr[3]; ne2000->macaddr[7] = ne2000->physaddr[3]; ne2000->macaddr[8] = ne2000->physaddr[4]; ne2000->macaddr[9] = ne2000->physaddr[4]; ne2000->macaddr[10] = ne2000->physaddr[5]; ne2000->macaddr[11] = ne2000->physaddr[5]; /* ne2k signature */ for (i = 12; i < 32; i++) { ne2000->macaddr[i] = 0x57; } /* Zero out registers and memory */ memset( & ne2000->CR, 0, sizeof(ne2000->CR) ); memset( & ne2000->ISR, 0, sizeof(ne2000->ISR)); memset( & ne2000->IMR, 0, sizeof(ne2000->IMR)); memset( & ne2000->DCR, 0, sizeof(ne2000->DCR)); memset( & ne2000->TCR, 0, sizeof(ne2000->TCR)); memset( & ne2000->TSR, 0, sizeof(ne2000->TSR)); memset( & ne2000->RSR, 0, sizeof(ne2000->RSR)); ne2000->tx_timer_active = 0; ne2000->local_dma = 0; ne2000->page_start = 0; ne2000->page_stop = 0; ne2000->bound_ptr = 0; ne2000->tx_page_start = 0; ne2000->num_coll = 0; ne2000->tx_bytes = 0; ne2000->fifo = 0; ne2000->remote_dma = 0; ne2000->remote_start = 0; ne2000->remote_bytes = 0; ne2000->tallycnt_0 = 0; ne2000->tallycnt_1 = 0; ne2000->tallycnt_2 = 0; ne2000->curr_page = 0; ne2000->rempkt_ptr = 0; ne2000->localpkt_ptr = 0; ne2000->address_cnt = 0; memset( & ne2000->mem, 0, sizeof(ne2000->mem)); /* Set power-up conditions */ ne2000->CR.stop = 1; ne2000->CR.rdma_cmd = 4; ne2000->ISR.reset = 1; ne2000->DCR.longaddr = 1; picint(1 << ne2000->base_irq); picintc(1 << ne2000->base_irq); } #include "bswap.h" /* read_cr/write_cr - utility routines for handling reads/writes to the Command Register */ uint32_t ne2000_read_cr(ne2000_t *ne2000) { uint32_t val; val = (((ne2000->CR.pgsel & 0x03) << 6) | ((ne2000->CR.rdma_cmd & 0x07) << 3) | (ne2000->CR.tx_packet << 2) | (ne2000->CR.start << 1) | (ne2000->CR.stop)); ne2000_log("%s: read CR returns 0x%02x\n", (network_card_current == 1) ? "NE2000" : "RTL8029AS", val); return val; } void ne2000_write_cr(ne2000_t *ne2000, uint32_t value) { ne2000_log("%s: wrote 0x%02x to CR\n", (network_card_current == 1) ? "NE2000" : "RTL8029AS", value); /* Validate remote-DMA */ if ((value & 0x38) == 0x00) { ne2000_log("CR write - invalid rDMA value 0\n"); value |= 0x20; /* dma_cmd == 4 is a safe default */ } /* Check for s/w reset */ if (value & 0x01) { ne2000->ISR.reset = 1; ne2000->CR.stop = 1; } else { ne2000->CR.stop = 0; } ne2000->CR.rdma_cmd = (value & 0x38) >> 3; /* If start command issued, the RST bit in the ISR */ /* must be cleared */ if ((value & 0x02) && !ne2000->CR.start) { ne2000->ISR.reset = 0; } ne2000->CR.start = ((value & 0x02) == 0x02); ne2000->CR.pgsel = (value & 0xc0) >> 6; /* Check for send-packet command */ if (ne2000->CR.rdma_cmd == 3) { /* Set up DMA read from receive ring */ ne2000->remote_start = ne2000->remote_dma = ne2000->bound_ptr * 256; ne2000->remote_bytes = (uint16_t) ne2000_chipmem_read(ne2000, ne2000->bound_ptr * 256 + 2, 2); ne2000_log("Sending buffer #x%x length %d\n", ne2000->remote_start, ne2000->remote_bytes); } /* Check for start-tx */ if ((value & 0x04) && ne2000->TCR.loop_cntl) { if (ne2000->TCR.loop_cntl != 1) { ne2000_log("Loop mode %d not supported\n", ne2000->TCR.loop_cntl); } else { ne2000_rx_frame(ne2000, &ne2000->mem[ne2000->tx_page_start*256 - BX_NE2K_MEMSTART], ne2000->tx_bytes); } } else if (value & 0x04) { if (ne2000->CR.stop || (!ne2000->CR.start && (network_card_current == 1))) { if (ne2000->tx_bytes == 0) /* njh@bandsman.co.uk */ { return; /* Solaris9 probe */ } ne2000_log("CR write - tx start, dev in reset\n"); } if (ne2000->tx_bytes == 0) { ne2000_log("CR write - tx start, tx bytes == 0\n"); } /* Send the packet to the system driver */ ne2000->CR.tx_packet = 1; if(!net_is_pcap) { slirp_input(&ne2000->mem[ne2000->tx_page_start*256 - BX_NE2K_MEMSTART], ne2000->tx_bytes); ne2000_log("ne2000 slirp sending packet\n"); } else if (net_is_pcap && (net_pcap != NULL)) { pcap_sendpacket(net_pcap, &ne2000->mem[ne2000->tx_page_start*256 - BX_NE2K_MEMSTART], ne2000->tx_bytes); ne2000_log("ne2000 pcap sending packet\n"); } /* some more debug */ if (ne2000->tx_timer_active) { ne2000_log("CR write, tx timer still active\n"); } ne2000_tx_event(ne2000, value); } /* Linux probes for an interrupt by setting up a remote-DMA read of 0 bytes with remote-DMA completion interrupts enabled. Detect this here */ if (ne2000->CR.rdma_cmd == 0x01 && ne2000->CR.start && ne2000->remote_bytes == 0) { ne2000->ISR.rdma_done = 1; if (ne2000->IMR.rdma_inte) { picint(1 << ne2000->base_irq); if (network_card_current == 1) { picintc(1 << ne2000->base_irq); } } } } /* chipmem_read/chipmem_write - access the 64K private RAM. The ne2000 memory is accessed through the data port of the asic (offset 0) after setting up a remote-DMA transfer. Both byte and word accesses are allowed. The first 16 bytes contains the MAC address at even locations, and there is 16K of buffer memory starting at 16K */ uint32_t ne2000_chipmem_read(ne2000_t *ne2000, uint32_t address, unsigned int io_len) { uint32_t retval = 0; if ((io_len == 2) && (address & 0x1)) { ne2000_log("unaligned chipmem word read\n"); } /* ROM'd MAC address */ if ((address >=0) && (address <= 31)) { retval = ne2000->macaddr[address % 32]; if ((io_len == 2) || (io_len == 4)) { retval |= (ne2000->macaddr[(address + 1) % 32] << 8); } if (io_len == 4) { retval |= (ne2000->macaddr[(address + 2) % 32] << 16); retval |= (ne2000->macaddr[(address + 3) % 32] << 24); } return (retval); } if ((address >= BX_NE2K_MEMSTART) && (address < BX_NE2K_MEMEND)) { retval = ne2000->mem[address - BX_NE2K_MEMSTART]; if ((io_len == 2) || (io_len == 4)) { retval |= (ne2000->mem[address - BX_NE2K_MEMSTART + 1] << 8); } if (io_len == 4) { retval |= (ne2000->mem[address - BX_NE2K_MEMSTART + 2] << 16); retval |= (ne2000->mem[address - BX_NE2K_MEMSTART + 3] << 24); } return (retval); } ne2000_log("out-of-bounds chipmem read, %04X\n", address); if (network_card_current == 1) { switch(io_len) { case 1: return 0xff; case 2: return 0xffff; } } else { return 0xff; } return 0xffff; } void ne2000_chipmem_write(ne2000_t *ne2000, uint32_t address, uint32_t value, unsigned io_len) { if ((io_len == 2) && (address & 0x1)) { ne2000_log("unaligned chipmem word write\n"); } if ((address >= BX_NE2K_MEMSTART) && (address < BX_NE2K_MEMEND)) { ne2000->mem[address - BX_NE2K_MEMSTART] = value & 0xff; if ((io_len == 2) || (io_len == 4)) { ne2000->mem[address - BX_NE2K_MEMSTART + 1] = value >> 8; } if (io_len == 4) { ne2000->mem[address - BX_NE2K_MEMSTART + 2] = value >> 16; ne2000->mem[address - BX_NE2K_MEMSTART + 3] = value >> 24; } } else { ne2000_log("out-of-bounds chipmem write, %04X\n", address); } } /* asic_read/asic_write - This is the high 16 bytes of i/o space (the lower 16 bytes is for the DS8390). Only two locations are used: offset 0, which is used for data transfer, and offset 0xf, which is used to reset the device. The data transfer port is used to as 'external' DMA to the DS8390. The chip has to have the DMA registers set up, and after that, insw/outsw instructions can be used to move the appropriate number of bytes to/from the device. */ uint32_t ne2000_asic_read(ne2000_t *ne2000, uint32_t offset, unsigned int io_len) { uint32_t retval = 0; switch (offset) { case 0x0: /* Data register */ /* A read remote-DMA command must have been issued, and the source-address and length registers must have been initialised. */ if (io_len > ne2000->remote_bytes) { ne2000_log("dma read underrun iolen=%d remote_bytes=%d\n",io_len,ne2000->remote_bytes); } ne2000_log("%s read DMA: addr=%4x remote_bytes=%d\n",(network_card_current == 1) ? "NE2000" : "RTL8029AS",ne2000->remote_dma,ne2000->remote_bytes); retval = ne2000_chipmem_read(ne2000, ne2000->remote_dma, io_len); /* The 8390 bumps the address and decreases the byte count by the selected word size after every access, not by the amount of data requested by the host (io_len). */ if (io_len == 4) { ne2000->remote_dma += io_len; } else { ne2000->remote_dma += (ne2000->DCR.wdsize + 1); } if (ne2000->remote_dma == ne2000->page_stop << 8) { ne2000->remote_dma = ne2000->page_start << 8; } /* keep s.remote_bytes from underflowing */ if (ne2000->remote_bytes > ne2000->DCR.wdsize) { if (io_len == 4) { ne2000->remote_bytes -= io_len; } else { ne2000->remote_bytes -= (ne2000->DCR.wdsize + 1); } } else { ne2000->remote_bytes = 0; } /* If all bytes have been written, signal remote-DMA complete */ if (ne2000->remote_bytes == 0) { ne2000->ISR.rdma_done = 1; if (ne2000->IMR.rdma_inte) { picint(1 << ne2000->base_irq); } } break; case 0xf: /* Reset register */ ne2000_reset(ne2000, BX_RESET_SOFTWARE); break; default: ne2000_log("asic read invalid address %04x\n", (unsigned) offset); break; } return (retval); } void ne2000_asic_write(ne2000_t *ne2000, uint32_t offset, uint32_t value, unsigned io_len) { ne2000_log("%s: asic write addr=0x%02x, value=0x%04x\n", (network_card_current == 1) ? "NE2000" : "RTL8029AS",(unsigned) offset, (unsigned) value); switch (offset) { case 0x0: /* Data register - see asic_read for a description */ if ((io_len > 1) && (ne2000->DCR.wdsize == 0)) { ne2000_log("dma write length %d on byte mode operation\n", io_len); break; } if (ne2000->remote_bytes == 0) { ne2000_log("dma write, byte count 0\n"); } ne2000_chipmem_write(ne2000, ne2000->remote_dma, value, io_len); if (io_len == 4) { ne2000->remote_dma += io_len; } else { ne2000->remote_dma += (ne2000->DCR.wdsize + 1); } if (ne2000->remote_dma == ne2000->page_stop << 8) { ne2000->remote_dma = ne2000->page_start << 8; } if (io_len == 4) { ne2000->remote_bytes -= io_len; } else { ne2000->remote_bytes -= (ne2000->DCR.wdsize + 1); } if (ne2000->remote_bytes > BX_NE2K_MEMSIZ) { ne2000->remote_bytes = 0; } /* If all bytes have been written, signal remote-DMA complete */ if (ne2000->remote_bytes == 0) { ne2000->ISR.rdma_done = 1; if (ne2000->IMR.rdma_inte) { picint(1 << ne2000->base_irq); } } break; case 0xf: /* Reset register */ /* end of reset pulse */ break; default: /* this is invalid, but happens under win95 device detection */ ne2000_log("asic write invalid address %04x, ignoring\n", (unsigned) offset); break; } } /* page0_read/page0_write - These routines handle reads/writes to the 'zeroth' page of the DS8390 register file */ uint32_t ne2000_page0_read(ne2000_t *ne2000, uint32_t offset, unsigned int io_len) { uint8_t value = 0; if (io_len > 1) { ne2000_log("bad length! page 0 read from register 0x%02x, len=%u\n", offset, io_len); /* encountered with win98 hardware probe */ return value; } switch (offset) { case 0x1: /* CLDA0 */ value = (ne2000->local_dma & 0xff); break; case 0x2: /* CLDA1 */ value = (ne2000->local_dma >> 8); break; case 0x3: /* BNRY */ value = ne2000->bound_ptr; break; case 0x4: /* TSR */ value = ((ne2000->TSR.ow_coll << 7) | (ne2000->TSR.cd_hbeat << 6) | (ne2000->TSR.fifo_ur << 5) | (ne2000->TSR.no_carrier << 4) | (ne2000->TSR.aborted << 3) | (ne2000->TSR.collided << 2) | (ne2000->TSR.tx_ok)); break; case 0x5: /* NCR */ value = ne2000->num_coll; break; case 0x6: /* FIFO */ /* reading FIFO is only valid in loopback mode */ ne2000_log("reading FIFO not supported yet\n"); value = ne2000->fifo; break; case 0x7: /* ISR */ value = ((ne2000->ISR.reset << 7) | (ne2000->ISR.rdma_done << 6) | (ne2000->ISR.cnt_oflow << 5) | (ne2000->ISR.overwrite << 4) | (ne2000->ISR.tx_err << 3) | (ne2000->ISR.rx_err << 2) | (ne2000->ISR.pkt_tx << 1) | (ne2000->ISR.pkt_rx)); break; case 0x8: /* CRDA0 */ value = (ne2000->remote_dma & 0xff); break; case 0x9: /* CRDA1 */ value = (ne2000->remote_dma >> 8); break; case 0xa: /* reserved / RTL8029ID0 */ if (network_card_current == 2) { value = 0x50; } else { ne2000_log("reserved read - page 0, 0xa\n"); value = 0xff; } break; case 0xb: /* reserved / RTL8029ID1 */ if (network_card_current == 2) { value = 0x43; } else { ne2000_log("reserved read - page 0, 0xb\n"); value = 0xff; } break; case 0xc: /* RSR */ value = ((ne2000->RSR.deferred << 7) | (ne2000->RSR.rx_disabled << 6) | (ne2000->RSR.rx_mbit << 5) | (ne2000->RSR.rx_missed << 4) | (ne2000->RSR.fifo_or << 3) | (ne2000->RSR.bad_falign << 2) | (ne2000->RSR.bad_crc << 1) | (ne2000->RSR.rx_ok)); break; case 0xd: /* CNTR0 */ value = ne2000->tallycnt_0; break; case 0xe: /* CNTR1 */ value = ne2000->tallycnt_1; break; case 0xf: /* CNTR2 */ value = ne2000->tallycnt_2; break; default: ne2000_log("page 0 register 0x%02x out of range\n", offset); break; } ne2000_log("page 0 read from register 0x%02x, value=0x%02x\n", offset, value); return value; } void ne2000_page0_write(ne2000_t *ne2000, uint32_t offset, uint32_t value, unsigned io_len) { uint8_t value2; /* It appears to be a common practice to use outw on page0 regs... */ /* break up outw into two outb's */ if (io_len == 2) { ne2000_page0_write(ne2000, offset, (value & 0xff), 1); if (offset < 0x0f) { ne2000_page0_write(ne2000, offset + 1, ((value >> 8) & 0xff), 1); } return; } ne2000_log("page 0 write to register 0x%02x, value=0x%02x\n", offset, value); switch (offset) { case 0x1: /* PSTART */ ne2000->page_start = value; break; case 0x2: /* PSTOP */ ne2000->page_stop = value; break; case 0x3: /* BNRY */ ne2000->bound_ptr = value; break; case 0x4: /* TPSR */ ne2000->tx_page_start = value; break; case 0x5: /* TBCR0 */ /* Clear out low byte and re-insert */ ne2000->tx_bytes &= 0xff00; ne2000->tx_bytes |= (value & 0xff); break; case 0x6: /* TBCR1 */ /* Clear out high byte and re-insert */ ne2000->tx_bytes &= 0x00ff; ne2000->tx_bytes |= ((value & 0xff) << 8); break; case 0x7: /* ISR */ value &= 0x7f; /* clear RST bit - status-only bit */ /* All other values are cleared iff the ISR bit is 1 */ ne2000->ISR.pkt_rx &= ~((int)((value & 0x01) == 0x01)); ne2000->ISR.pkt_tx &= ~((int)((value & 0x02) == 0x02)); ne2000->ISR.rx_err &= ~((int)((value & 0x04) == 0x04)); ne2000->ISR.tx_err &= ~((int)((value & 0x08) == 0x08)); ne2000->ISR.overwrite &= ~((int)((value & 0x10) == 0x10)); ne2000->ISR.cnt_oflow &= ~((int)((value & 0x20) == 0x20)); ne2000->ISR.rdma_done &= ~((int)((value & 0x40) == 0x40)); value = ((ne2000->ISR.rdma_done << 6) | (ne2000->ISR.cnt_oflow << 5) | (ne2000->ISR.overwrite << 4) | (ne2000->ISR.tx_err << 3) | (ne2000->ISR.rx_err << 2) | (ne2000->ISR.pkt_tx << 1) | (ne2000->ISR.pkt_rx)); value &= ((ne2000->IMR.rdma_inte << 6) | (ne2000->IMR.cofl_inte << 5) | (ne2000->IMR.overw_inte << 4) | (ne2000->IMR.txerr_inte << 3) | (ne2000->IMR.rxerr_inte << 2) | (ne2000->IMR.tx_inte << 1) | (ne2000->IMR.rx_inte)); if (value == 0) { picintc(1 << ne2000->base_irq); } break; case 0x8: /* RSAR0 */ /* Clear out low byte and re-insert */ ne2000->remote_start &= 0xff00; ne2000->remote_start |= (value & 0xff); ne2000->remote_dma = ne2000->remote_start; break; case 0x9: /* RSAR1 */ /* Clear out high byte and re-insert */ ne2000->remote_start &= 0x00ff; ne2000->remote_start |= ((value & 0xff) << 8); ne2000->remote_dma = ne2000->remote_start; break; case 0xa: /* RBCR0 */ /* Clear out low byte and re-insert */ ne2000->remote_bytes &= 0xff00; ne2000->remote_bytes |= (value & 0xff); break; case 0xb: /* RBCR1 */ /* Clear out high byte and re-insert */ ne2000->remote_bytes &= 0x00ff; ne2000->remote_bytes |= ((value & 0xff) << 8); break; case 0xc: /* RCR */ /* Check if the reserved bits are set */ if (value & 0xc0) { ne2000_log("RCR write, reserved bits set\n"); } /* Set all other bit-fields */ ne2000->RCR.errors_ok = ((value & 0x01) == 0x01); ne2000->RCR.runts_ok = ((value & 0x02) == 0x02); ne2000->RCR.broadcast = ((value & 0x04) == 0x04); ne2000->RCR.multicast = ((value & 0x08) == 0x08); ne2000->RCR.promisc = ((value & 0x10) == 0x10); ne2000->RCR.monitor = ((value & 0x20) == 0x20); /* Monitor bit is a little suspicious... */ if (value & 0x20) { ne2000_log("RCR write, monitor bit set!\n"); } break; case 0xd: /* TCR */ /* Check reserved bits */ if (value & 0xe0) { ne2000_log("TCR write, reserved bits set\n"); } /* Test loop mode (not supported) */ if (value & 0x06) { ne2000->TCR.loop_cntl = (value & 0x6) >> 1; ne2000_log("TCR write, loop mode %d not supported\n", ne2000->TCR.loop_cntl); } else { ne2000->TCR.loop_cntl = 0; } /* Inhibit-CRC not supported. */ if (value & 0x01) { ne2000_log("TCR write, inhibit-CRC not supported\n"); } /* Auto-transmit disable very suspicious */ if (value & 0x08) { ne2000_log("TCR write, auto transmit disable not supported\n"); } /* Allow collision-offset to be set, although not used */ ne2000->TCR.coll_prio = ((value & 0x08) == 0x08); break; case 0xe: /* DCR */ /* the loopback mode is not suppported yet */ if (!(value & 0x08)) { ne2000_log("DCR write, loopback mode selected\n"); } /* It is questionable to set longaddr and auto_rx, since they aren't supported on the ne2000. Print a warning and continue */ if (value & 0x04) { ne2000_log("DCR write - LAS set ???\n"); } if (value & 0x10) { ne2000_log("DCR write - AR set ???\n"); } /* Set other values. */ ne2000->DCR.wdsize = ((value & 0x01) == 0x01); ne2000->DCR.endian = ((value & 0x02) == 0x02); ne2000->DCR.longaddr = ((value & 0x04) == 0x04); /* illegal ? */ ne2000->DCR.loop = ((value & 0x08) == 0x08); ne2000->DCR.auto_rx = ((value & 0x10) == 0x10); /* also illegal ? */ ne2000->DCR.fifo_size = (value & 0x50) >> 5; break; case 0xf: /* IMR */ /* Check for reserved bit */ if (value & 0x80) { ne2000_log("IMR write, reserved bit set\n"); } /* Set other values */ ne2000->IMR.rx_inte = ((value & 0x01) == 0x01); ne2000->IMR.tx_inte = ((value & 0x02) == 0x02); ne2000->IMR.rxerr_inte = ((value & 0x04) == 0x04); ne2000->IMR.txerr_inte = ((value & 0x08) == 0x08); ne2000->IMR.overw_inte = ((value & 0x10) == 0x10); ne2000->IMR.cofl_inte = ((value & 0x20) == 0x20); ne2000->IMR.rdma_inte = ((value & 0x40) == 0x40); value2 = ((ne2000->ISR.rdma_done << 6) | (ne2000->ISR.cnt_oflow << 5) | (ne2000->ISR.overwrite << 4) | (ne2000->ISR.tx_err << 3) | (ne2000->ISR.rx_err << 2) | (ne2000->ISR.pkt_tx << 1) | (ne2000->ISR.pkt_rx)); if (((value & value2) & 0x7f) == 0) { picintc(1 << ne2000->base_irq); } else { picint(1 << ne2000->base_irq); } break; default: ne2000_log("page 0 write, bad register 0x%02x\n", offset); break; } } /* page1_read/page1_write - These routines handle reads/writes to the first page of the DS8390 register file */ uint32_t ne2000_page1_read(ne2000_t *ne2000, uint32_t offset, unsigned int io_len) { ne2000_log("page 1 read from register 0x%02x, len=%u\n", offset, io_len); switch (offset) { case 0x1: /* PAR0-5 */ case 0x2: case 0x3: case 0x4: case 0x5: case 0x6: return (ne2000->physaddr[offset - 1]); case 0x7: /* CURR */ ne2000_log("returning current page: 0x%02x\n", (ne2000->curr_page)); return (ne2000->curr_page); case 0x8: /* MAR0-7 */ case 0x9: case 0xa: case 0xb: case 0xc: case 0xd: case 0xe: case 0xf: return (ne2000->mchash[offset - 8]); default: ne2000_log("page 1 read register 0x%02x out of range\n", offset); return 0; } } void ne2000_page1_write(ne2000_t *ne2000, uint32_t offset, uint32_t value, unsigned io_len) { ne2000_log("page 1 write to register 0x%02x, len=%u, value=0x%04x\n", offset, io_len, value); switch (offset) { case 0x1: /* PAR0-5 */ case 0x2: case 0x3: case 0x4: case 0x5: case 0x6: ne2000->physaddr[offset - 1] = value; if (offset == 6) { ne2000_log("Physical address set to %02x:%02x:%02x:%02x:%02x:%02x\n", ne2000->physaddr[0], ne2000->physaddr[1], ne2000->physaddr[2], ne2000->physaddr[3], ne2000->physaddr[4], ne2000->physaddr[5]); } break; case 0x7: /* CURR */ ne2000->curr_page = value; break; case 0x8: /* MAR0-7 */ case 0x9: case 0xa: case 0xb: case 0xc: case 0xd: case 0xe: case 0xf: ne2000->mchash[offset - 8] = value; break; default: ne2000_log("page 1 write register 0x%02x out of range\n", offset); break; } } /* page2_read/page2_write - These routines handle reads/writes to the second page of the DS8390 register file */ uint32_t ne2000_page2_read(ne2000_t *ne2000, uint32_t offset, unsigned int io_len) { ne2000_log("page 2 read from register 0x%02x, len=%u\n", offset, io_len); switch (offset) { case 0x1: /* PSTART */ return (ne2000->page_start); case 0x2: /* PSTOP */ return (ne2000->page_stop); case 0x3: /* Remote Next-packet pointer */ return (ne2000->rempkt_ptr); case 0x4: /* TPSR */ return (ne2000->tx_page_start); case 0x5: /* Local Next-packet pointer */ return (ne2000->localpkt_ptr); case 0x6: /* Address counter (upper) */ return (ne2000->address_cnt >> 8); case 0x7: /* Address counter (lower) */ return (ne2000->address_cnt & 0xff); case 0x8: /* Reserved */ case 0x9: case 0xa: case 0xb: ne2000_log("reserved read - page 2, register 0x%02x\n", offset); return (0xff); case 0xc: /* RCR */ return ((ne2000->RCR.monitor << 5) | (ne2000->RCR.promisc << 4) | (ne2000->RCR.multicast << 3) | (ne2000->RCR.broadcast << 2) | (ne2000->RCR.runts_ok << 1) | (ne2000->RCR.errors_ok)); case 0xd: /* TCR */ return ((ne2000->TCR.coll_prio << 4) | (ne2000->TCR.ext_stoptx << 3) | ((ne2000->TCR.loop_cntl & 0x3) << 1) | (ne2000->TCR.crc_disable)); case 0xe: /* DCR */ return (((ne2000->DCR.fifo_size & 0x3) << 5) | (ne2000->DCR.auto_rx << 4) | (ne2000->DCR.loop << 3) | (ne2000->DCR.longaddr << 2) | (ne2000->DCR.endian << 1) | (ne2000->DCR.wdsize)); case 0xf: /* IMR */ return ((ne2000->IMR.rdma_inte << 6) | (ne2000->IMR.cofl_inte << 5) | (ne2000->IMR.overw_inte << 4) | (ne2000->IMR.txerr_inte << 3) | (ne2000->IMR.rxerr_inte << 2) | (ne2000->IMR.tx_inte << 1) | (ne2000->IMR.rx_inte)); default: ne2000_log("page 2 register 0x%02x out of range\n", offset); break; } return (0); } void ne2000_page2_write(ne2000_t *ne2000, uint32_t offset, uint32_t value, unsigned io_len) { /* Maybe all writes here should be BX_PANIC()'d, since they affect internal operation, but let them through for now and print a warning. */ ne2000_log("page 2 write to register 0x%02x, len=%u, value=0x%04x\n", offset, io_len, value); switch (offset) { case 0x1: /* CLDA0 */ /* Clear out low byte and re-insert */ ne2000->local_dma &= 0xff00; ne2000->local_dma |= (value & 0xff); break; case 0x2: /* CLDA1 */ /* Clear out high byte and re-insert */ ne2000->local_dma &= 0x00ff; ne2000->local_dma |= ((value & 0xff) << 8); break; case 0x3: /* Remote Next-pkt pointer */ ne2000->rempkt_ptr = value; break; case 0x4: ne2000_log("page 2 write to reserved register 0x04\n"); break; case 0x5: /* Local Next-packet pointer */ ne2000->localpkt_ptr = value; break; case 0x6: /* Address counter (upper) */ /* Clear out high byte and re-insert */ ne2000->address_cnt &= 0x00ff; ne2000->address_cnt |= ((value & 0xff) << 8); break; case 0x7: /* Address counter (lower) */ /* Clear out low byte and re-insert */ ne2000->address_cnt &= 0xff00; ne2000->address_cnt |= (value & 0xff); break; case 0x8: case 0x9: case 0xa: case 0xb: case 0xc: case 0xd: case 0xe: case 0xf: ne2000_log("page 2 write to reserved register 0x%02x\n", offset); break; default: ne2000_log("page 2 write, illegal register 0x%02x\n", offset); break; } } /* page3_read/page3_write - writes to this page are illegal */ uint32_t ne2000_page3_read(ne2000_t *ne2000, uint32_t offset, unsigned int io_len) { if (network_card_current == 2) { switch (offset) { case 0x3: /* CONFIG0 */ return (0); case 0x5: /* CONFIG2 */ return (0x40); case 0x6: /* CONFIG3 */ return (0x40); default: ne2000_log("page 3 read register 0x%02x attempted\n", offset); return (0); } } else { ne2000_log("page 3 read register 0x%02x attempted\n", offset); return (0); } } void ne2000_page3_write(ne2000_t *ne2000, uint32_t offset, uint32_t value, unsigned io_len) { ne2000_log("page 3 write register 0x%02x attempted\n", offset); return; } void ne2000_tx_event(void *p, uint32_t val) { ne2000_t *ne2000 = (ne2000_t *)p; ne2000_log("tx_timer\n"); ne2000->CR.tx_packet = 0; ne2000->TSR.tx_ok = 1; ne2000->ISR.pkt_tx = 1; /* Generate an interrupt if not masked */ if (ne2000->IMR.tx_inte) { picint(1 << ne2000->base_irq); } ne2000->tx_timer_active = 0; } /* read_handler/read - i/o 'catcher' function called from BOCHS mainline when the CPU attempts a read in the i/o space registered by this ne2000 instance */ uint32_t ne2000_read(ne2000_t *ne2000, uint32_t address, unsigned io_len) { uint32_t retval = 0; int offset = address - ne2000->base_address; ne2000_log("%s: read addr %x, len %d\n", (network_card_current == 1) ? "NE2000" : "RTL8029AS", address, io_len); if (offset >= 0x10) { retval = ne2000_asic_read(ne2000, offset - 0x10, io_len); } else if (offset == 0x00) { retval = ne2000_read_cr(ne2000); } else { switch (ne2000->CR.pgsel) { case 0x00: retval = ne2000_page0_read(ne2000, offset, io_len); break; case 0x01: retval = ne2000_page1_read(ne2000, offset, io_len); break; case 0x02: retval = ne2000_page2_read(ne2000, offset, io_len); break; case 0x03: retval = ne2000_page3_read(ne2000, offset, io_len); break; default: ne2000_log("unknown value of pgsel in read - %d\n", ne2000->CR.pgsel); break; } } return (retval); } void ne2000_write(ne2000_t *ne2000, uint32_t address, uint32_t value, unsigned io_len) { int offset = address - ne2000->base_address; ne2000_log("%s: write addr %x, value %x len %d\n", (network_card_current == 1) ? "NE2000" : "RTL8029AS", address, value, io_len); /* The high 16 bytes of i/o space are for the ne2000 asic - the low 16 bytes are for the DS8390, with the current page being selected by the PS0,PS1 registers in the command register */ if (offset >= 0x10) { ne2000_asic_write(ne2000, offset - 0x10, value, io_len); } else if (offset == 0x00) { ne2000_write_cr(ne2000, value); } else { switch (ne2000->CR.pgsel) { case 0x00: ne2000_page0_write(ne2000, offset, value, io_len); break; case 0x01: ne2000_page1_write(ne2000, offset, value, io_len); break; case 0x02: ne2000_page2_write(ne2000, offset, value, io_len); break; case 0x03: ne2000_page3_write(ne2000, offset, value, io_len); break; default: ne2000_log("unknown value of pgsel in write - %d\n", ne2000->CR.pgsel); break; } } } /* * mcast_index() - return the 6-bit index into the multicast * table. Stolen unashamedly from FreeBSD's if_ed.c */ static int mcast_index(const void *dst) { #define POLYNOMIAL 0x04c11db6 unsigned long crc = 0xffffffffL; int carry, i, j; unsigned char b; unsigned char *ep = (unsigned char *) dst; for (i = 6; --i >= 0;) { b = *ep++; for (j = 8; --j >= 0;) { carry = ((crc & 0x80000000L) ? 1 : 0) ^ (b & 0x01); crc <<= 1; b >>= 1; if (carry) { crc = ((crc ^ POLYNOMIAL) | carry); } } } return (crc >> 26); #undef POLYNOMIAL } /* * rx_frame() - called by the platform-specific code when an * ethernet frame has been received. The destination address * is tested to see if it should be accepted, and if the * rx ring has enough room, it is copied into it and * the receive process is updated */ void ne2000_rx_frame(void *p, const void *buf, int io_len) { ne2000_t *ne2000 = (ne2000_t *)p; int pages; int avail; int idx; int nextpage; uint8_t pkthdr[4]; uint8_t *pktbuf = (uint8_t *) buf; uint8_t *startptr; static uint8_t bcast_addr[6] = {0xff,0xff,0xff,0xff,0xff,0xff}; uint32_t mac_cmp32[2]; uint16_t mac_cmp16[2]; if(io_len != 60) { ne2000_log("rx_frame with length %d\n", io_len); } if ((ne2000->CR.stop != 0) || (ne2000->page_start == 0)) { return; } /* Add the pkt header + CRC to the length, and work out how many 256-byte pages the frame would occupy */ pages = (io_len + 4 + 4 + 255)/256; if (ne2000->curr_page < ne2000->bound_ptr) { avail = ne2000->bound_ptr - ne2000->curr_page; } else { avail = (ne2000->page_stop - ne2000->page_start) - (ne2000->curr_page - ne2000->bound_ptr); } /* Avoid getting into a buffer overflow condition by not attempting to do partial receives. The emulation to handle this condition seems particularly painful. */ if ((avail < pages) #if BX_NE2K_NEVER_FULL_RING || (avail == pages) #endif ) { ne2000_log("no space\n"); return; } if ((io_len < 40/*60*/) && !ne2000->RCR.runts_ok) { ne2000_log("rejected small packet, length %d\n", io_len); return; } /* some computers don't care... */ if (io_len < 60) { io_len=60; } /* Do address filtering if not in promiscuous mode */ if (! ne2000->RCR.promisc) { /* Received. */ mac_cmp32[0] = *(uint32_t *) (buf); mac_cmp16[0] = *(uint16_t *) (((uint8_t *) buf) + 4); /* Local. */ mac_cmp32[1] = *(uint32_t *) (bcast_addr); mac_cmp16[1] = *(uint16_t *) (bcast_addr+4); if ((mac_cmp32[0] == mac_cmp32[1]) && (mac_cmp16[0] == mac_cmp16[1])) { if (!ne2000->RCR.broadcast) { return; } } else if (pktbuf[0] & 0x01) { if (! ne2000->RCR.multicast) { return; } idx = mcast_index(buf); if (!(ne2000->mchash[idx >> 3] & (1 << (idx & 0x7)))) { return; } } else if (0 != memcmp(buf, ne2000->physaddr, 6)) { return; } } else { ne2000_log("rx_frame promiscuous receive\n"); } ne2000_log("rx_frame %d to %x:%x:%x:%x:%x:%x from %x:%x:%x:%x:%x:%x\n", io_len, pktbuf[0], pktbuf[1], pktbuf[2], pktbuf[3], pktbuf[4], pktbuf[5], pktbuf[6], pktbuf[7], pktbuf[8], pktbuf[9], pktbuf[10], pktbuf[11]); nextpage = ne2000->curr_page + pages; if (nextpage >= ne2000->page_stop) { nextpage -= ne2000->page_stop - ne2000->page_start; } /* Setup packet header */ pkthdr[0] = 0; /* rx status - old behavior pkthdr[0] = 1; /* Probably better to set it all the time rather than set it to 0, which is clearly wrong. */ if (pktbuf[0] & 0x01) { pkthdr[0] |= 0x20; /* rx status += multicast packet */ } pkthdr[1] = nextpage; /* ptr to next packet */ pkthdr[2] = (io_len + 4) & 0xff; /* length-low */ pkthdr[3] = (io_len + 4) >> 8; /* length-hi */ /* copy into buffer, update curpage, and signal interrupt if config'd */ startptr = & ne2000->mem[ne2000->curr_page * 256 - BX_NE2K_MEMSTART]; if ((nextpage > ne2000->curr_page) || ((ne2000->curr_page + pages) == ne2000->page_stop)) { *(uint32_t *) startptr = *(uint32_t *) pkthdr; memcpy(startptr + 4, buf, io_len); ne2000->curr_page = nextpage; } else { int endbytes = (ne2000->page_stop - ne2000->curr_page) * 256; *(uint32_t *) startptr = *(uint32_t *) pkthdr; memcpy(startptr + 4, buf, endbytes - 4); startptr = & ne2000->mem[ne2000->page_start * 256 - BX_NE2K_MEMSTART]; memcpy(startptr, (void *)(pktbuf + endbytes - 4), io_len - endbytes + 8); ne2000->curr_page = nextpage; } ne2000->RSR.rx_ok = 1; if (pktbuf[0] & 0x80) { ne2000->RSR.rx_mbit = 1; } ne2000->ISR.pkt_rx = 1; if (ne2000->IMR.rx_inte) { picint(1 << ne2000->base_irq); } } uint8_t ne2000_readb(uint16_t addr, void *p) { ne2000_t *ne2000 = (ne2000_t *)p; return ne2000_read(ne2000, addr, 1); } uint16_t ne2000_readw(uint16_t addr, void *p) { ne2000_t *ne2000 = (ne2000_t *)p; if (ne2000->DCR.wdsize & 1) { return ne2000_read(ne2000, addr, 2); } else { return ne2000_read(ne2000, addr, 1); } } uint32_t ne2000_readl(uint16_t addr, void *p) { ne2000_t *ne2000 = (ne2000_t *)p; return ne2000_read(ne2000, addr, 4); } void ne2000_writeb(uint16_t addr, uint8_t val, void *p) { ne2000_t *ne2000 = (ne2000_t *)p; ne2000_write(ne2000, addr, val, 1); } void ne2000_writew(uint16_t addr, uint16_t val, void *p) { ne2000_t *ne2000 = (ne2000_t *)p; if (ne2000->DCR.wdsize & 1) { ne2000_write(ne2000, addr, val, 2); } else { ne2000_write(ne2000, addr, val, 1); } } void ne2000_writel(uint16_t addr, uint32_t val, void *p) { ne2000_t *ne2000 = (ne2000_t *)p; ne2000_write(ne2000, addr, val, 4); } void ne2000_poller(void *p) { ne2000_t *ne2000 = (ne2000_t *)p; struct queuepacket *qp; const unsigned char *data; struct pcap_pkthdr h; uint32_t mac_cmp32[2]; uint16_t mac_cmp16[2]; uint8_t temp_mac[6] = { 0, 0, 0, 0, 0, 0 }; ne2000_mac(temp_mac); if (!net_is_pcap) { while(QueuePeek(slirpq) > 0) { qp=QueueDelete(slirpq); if((ne2000->DCR.loop == 0) || (ne2000->TCR.loop_cntl != 0)) { free(qp); return; } ne2000_rx_frame(ne2000,&qp->data,qp->len); ne2000_log("ne2000 inQ:%d got a %dbyte packet @%d\n",QueuePeek(slirpq),qp->len,qp); free(qp); } fizz++; if (fizz>1200) { fizz=0;slirp_tic(); } } /* end slirp */ else if (net_is_pcap && (net_pcap != NULL)) { if((ne2000->DCR.loop == 0) || (ne2000->TCR.loop_cntl != 0)) { return; } data=pcap_next(net_pcap,&h); if(data==0x0) { return; } /* Received. */ mac_cmp32[0] = *(uint32_t *) (data+6); mac_cmp16[0] = *(uint16_t *) (data+10); /* Local. */ mac_cmp32[1] = *(uint32_t *) (temp_mac); mac_cmp16[1] = *(uint16_t *) (temp_mac + 4); if ((mac_cmp32[0] != mac_cmp32[1]) || (mac_cmp16[0] != mac_cmp16[1])) { ne2000_rx_frame(ne2000,data,h.caplen); } } } typedef union { uint32_t addr; uint8_t addr_regs[4]; } bar_t; uint8_t ne2000_pci_regs[256]; bar_t ne2000_pci_bar[2]; uint32_t bios_addr = 0xD0000; uint32_t old_base_addr = 0; uint32_t bios_size = 0; uint32_t bios_mask = 0; void ne2000_io_set(uint16_t addr, ne2000_t *ne2000) { old_base_addr = addr; if (network_card_current == 1) { io_sethandler(addr, 0x0010, ne2000_readb, NULL, NULL, ne2000_writeb, NULL, NULL, ne2000); io_sethandler(addr+0x10, 0x0010, ne2000_readb, ne2000_readw, NULL, ne2000_writeb, ne2000_writew, NULL, ne2000); io_sethandler(addr+0x1f, 0x0001, ne2000_readb, NULL, NULL, ne2000_writeb, NULL, NULL, ne2000); } else { io_sethandler(addr, 0x0010, ne2000_readb, ne2000_readw, ne2000_readl, ne2000_writeb, ne2000_writew, ne2000_writel, ne2000); io_sethandler(addr+0x10, 0x0010, ne2000_readb, ne2000_readw, ne2000_readl, ne2000_writeb, ne2000_writew, ne2000_writel, ne2000); io_sethandler(addr+0x1f, 0x0001, ne2000_readb, ne2000_readw, ne2000_readl, ne2000_writeb, ne2000_writew, ne2000_writel, ne2000); } } void ne2000_io_remove(int16_t addr, ne2000_t *ne2000) { if (network_card_current == 1) { io_removehandler(addr, 0x0010, ne2000_readb, NULL, NULL, ne2000_writeb, NULL, NULL, ne2000); io_removehandler(addr+0x10, 0x0010, ne2000_readb, ne2000_readw, NULL, ne2000_writeb, ne2000_writew, NULL, ne2000); io_removehandler(addr+0x1f, 0x0001, ne2000_readb, NULL, NULL, ne2000_writeb, NULL, NULL, ne2000); } else { io_removehandler(addr, 0x0010, ne2000_readb, ne2000_readw, ne2000_readl, ne2000_writeb, ne2000_writew, ne2000_writel, ne2000); io_removehandler(addr+0x10, 0x0010, ne2000_readb, ne2000_readw, ne2000_readl, ne2000_writeb, ne2000_writew, ne2000_writel, ne2000); io_removehandler(addr+0x1f, 0x0001, ne2000_readb, ne2000_readw, ne2000_readl, ne2000_writeb, ne2000_writew, ne2000_writel, ne2000); } } uint8_t ne2000_pci_read(int func, int addr, void *p) { switch (addr) { case 0x00: return 0xec; case 0x01: return 0x10; case 0x02: return 0x29; case 0x03: return 0x80; case 0x2C: return 0xF4; case 0x2D: return 0x1A; case 0x2E: return 0x00; case 0x2F: return 0x11; case 0x04: return ne2000_pci_regs[0x04]; /*Respond to IO and memory accesses*/ case 0x05: return ne2000_pci_regs[0x05]; case 0x07: return 2; case 0x08: return 0; /*Revision ID*/ case 0x09: return 0; /*Programming interface*/ case 0x0B: return ne2000_pci_regs[0x0B]; case 0x10: return 1; /*I/O space*/ case 0x11: return ne2000_pci_bar[0].addr_regs[1]; case 0x12: return ne2000_pci_bar[0].addr_regs[2]; case 0x13: return ne2000_pci_bar[0].addr_regs[3]; case 0x30: return ne2000_pci_bar[1].addr_regs[0] & 0x01; /*BIOS ROM address*/ case 0x31: return (ne2000_pci_bar[1].addr_regs[1] & bios_mask) | 0x18; case 0x32: return ne2000_pci_bar[1].addr_regs[2]; case 0x33: return ne2000_pci_bar[1].addr_regs[3]; case 0x3C: return ne2000_pci_regs[0x3C]; case 0x3D: return ne2000_pci_regs[0x3D]; } return 0; } void ne2000_update_bios(ne2000_t *ne2000) { int reg_bios_enable; reg_bios_enable = 1; /* PCI BIOS stuff, just enable_disable. */ if (!disable_netbios && reg_bios_enable) { mem_mapping_enable(&ne2000->bios_rom.mapping); mem_mapping_set_addr(&ne2000->bios_rom.mapping, bios_addr, 0x10000); ne2000_log("Network BIOS now at: %08X\n", bios_addr); } else { mem_mapping_disable(&ne2000->bios_rom.mapping); if (network_card_current == 2) ne2000_pci_bar[1].addr = 0; } } void ne2000_pci_write(int func, int addr, uint8_t val, void *p) { ne2000_t *ne2000 = (ne2000_t *) p; switch (addr) { case 0x04: ne2000_io_remove(ne2000->base_address, ne2000); if (val & PCI_COMMAND_IO) { ne2000_io_set(ne2000->base_address, ne2000); } ne2000_pci_regs[addr] = val; break; case 0x10: val &= 0xfc; val |= 1; case 0x11: case 0x12: case 0x13: /* I/O Base set. */ /* First, remove the old I/O, if old base was >= 0x280. */ ne2000_io_remove(ne2000->base_address, ne2000); /* Then let's set the PCI regs. */ ne2000_pci_bar[0].addr_regs[addr & 3] = val; /* Then let's calculate the new I/O base. */ ne2000->base_address = ne2000_pci_bar[0].addr & 0xff00; /* Log the new base. */ ne2000_log("NE2000 RTL8029AS PCI: New I/O base is %04X\n" , ne2000->base_address); /* We're done, so get out of the here. */ if (val & PCI_COMMAND_IO) { ne2000_io_set(ne2000->base_address, ne2000); } return; case 0x30: case 0x31: case 0x32: case 0x33: ne2000_pci_bar[1].addr_regs[addr & 3] = val; ne2000_pci_bar[1].addr_regs[1] &= bios_mask; bios_addr = ne2000_pci_bar[1].addr & 0xffffe000; ne2000_pci_bar[1].addr &= 0xffffe000; ne2000_pci_bar[1].addr |= 0x1801; ne2000_update_bios(ne2000); return; /* Commented out until an APIC controller is emulated for the PIIX3, otherwise the RTL-8029/AS will not get an IRQ on boards using the PIIX3. */ #if 0 case 0x3C: ne2000_pci_regs[addr] = val; if (val != 0xFF) { ne2000_log("NE2000 IRQ now: %i\n", val); ne2000_setirq(ne2000, val); } return; #endif } } void ne2000_rom_init(ne2000_t *ne2000, wchar_t *s) { FILE *f = romfopen(s, L"rb"); uint32_t temp; if(!f) { disable_netbios = 1; ne2000_update_bios(ne2000); return; } fseek(f, 0, SEEK_END); temp = ftell(f); fclose(f); bios_size = 0x10000; if (temp <= 0x8000) { bios_size = 0x8000; } if (temp <= 0x4000) { bios_size = 0x4000; } if (temp <= 0x2000) { bios_size = 0x2000; } bios_mask = (bios_size >> 8) & 0xff; bios_mask = (0x100 - bios_mask) & 0xff; rom_init(&ne2000->bios_rom, s, 0xd0000, bios_size, bios_size - 1, 0, MEM_MAPPING_EXTERNAL); } static char errbuf[32768]; void *ne2000_init(void) { int rc; int config_net_type; int irq; int pcap_device_available = 0; int is_rtl8029as = 0; ne2000_t *ne2000 = malloc(sizeof(ne2000_t)); memset(ne2000, 0, sizeof(ne2000_t)); uint8_t temp_mac[6] = { 0, 0, 0, 0, 0, 0 }; if (PCI && (network_card_current == 2)) { is_rtl8029as = 1; } else { network_card_current = 1; is_rtl8029as = 0; } if (is_rtl8029as) { ne2000->base_address = 0x340; } else { ne2000->base_address = device_get_config_int("addr"); } disable_netbios = device_get_config_int("disable_netbios"); irq = device_get_config_int("irq"); ne2000_setirq(ne2000, irq); config_net_type = device_get_config_int("net_type"); /* Network type is now specified in device config. */ net_is_pcap = config_net_type ? 0 : 1; if(!strcmp("nothing", config_get_string(NULL, "pcap_device", "nothing"))) { net_is_pcap = 0; pcap_device_available = 0; } else { pcap_device_available = 1; } ne2000_log("net_is_pcap = %i\n", net_is_pcap); if (is_rtl8029as) { pci_add(ne2000_pci_read, ne2000_pci_write, ne2000); } ne2000_io_set(ne2000->base_address, ne2000); ne2000_mac(temp_mac); ne2000_mac(ne2000->physaddr); if (!disable_netbios) { ne2000_rom_init(ne2000, is_rtl8029as ? L"roms/rtl8029as.rom" : L"roms/ne2000.rom"); if (is_rtl8029as) { mem_mapping_disable(&ne2000->bios_rom.mapping); } } if (is_rtl8029as) { ne2000_pci_regs[0x04] = 1; ne2000_pci_regs[0x05] = 0; ne2000_pci_regs[0x07] = 2; /* Network controller. */ ne2000_pci_regs[0x0B] = 2; ne2000_pci_bar[0].addr_regs[0] = 1; if (disable_netbios) { ne2000_pci_bar[1].addr = 0; bios_addr = 0; } else { ne2000_pci_bar[1].addr = 0x000F8000; ne2000_pci_bar[1].addr_regs[1] = bios_mask; ne2000_pci_bar[1].addr |= 0x1801; bios_addr = 0xD0000; } ne2000_pci_regs[0x3C] = irq; pclog("RTL8029AS IRQ: %i\n", ne2000_pci_regs[0x3C]); ne2000_pci_regs[0x3D] = 1; memset(rtl8029as_eeprom, 0, 128); rtl8029as_eeprom[0x76] = rtl8029as_eeprom[0x7A] = rtl8029as_eeprom[0x7E] = 0x29; rtl8029as_eeprom[0x77] = rtl8029as_eeprom[0x7B] = rtl8029as_eeprom[0x7F] = 0x80; rtl8029as_eeprom[0x78] = rtl8029as_eeprom[0x7C] = 0x10; rtl8029as_eeprom[0x79] = rtl8029as_eeprom[0x7D] = 0xEC; } ne2000_reset(ne2000, BX_RESET_HARDWARE); network_add_handler(ne2000_poller, ne2000); ne2000_log("ne2000 %s init 0x%X %d\tnet_is_pcap is %d\n",is_rtl8029as ? "pci" : "isa",ne2000->base_address,device_get_config_int("irq"),net_is_pcap); /* need a switch statment for more network types. */ if (!net_is_pcap) { initialize_slirp: ne2000_log("ne2000 initalizing SLiRP\n"); net_is_pcap=0; rc=slirp_init(); ne2000_log("ne2000 slirp_init returned: %d\n",rc); if (!rc) { ne2000_log("ne2000 slirp initalized!\n"); net_slirp_inited = 1; slirpq = QueueCreate(); fizz=0; ne2000_log("ne2000 slirpq is %x\n",&slirpq); } else { net_slirp_inited = 0; if (pcap_device_available) { net_is_pcap = 1; goto initialize_pcap; } else { ne2000_log("Neither SLiRP nor PCap is available on your host, disabling network adapter...\n"); free(ne2000); network_card_current = 0; resetpchard(); return NULL; } } } else { initialize_pcap: ne2000_log("ne2000 initalizing libpcap\n"); ne2000_log("ne2000 Pcap version [%s]\n",pcap_lib_version()); if((net_pcap=pcap_open_live(config_get_string(NULL,"pcap_device","nothing"),1518,1,15,errbuf))==0) { ne2000_log("ne2000 pcap_open_live error on %s!\n",config_get_string(NULL,"pcap_device","whatever the ethernet is")); net_is_pcap=0; return(ne2000); /* YUCK!!! */ } /* Time to check that we are in non-blocking mode. */ rc=pcap_getnonblock(net_pcap,errbuf); ne2000_log("ne2000 pcap is currently in %s mode\n",rc? "non-blocking":"blocking"); switch(rc) { case 0: ne2000_log("ne2000 Setting interface to non-blocking mode.."); rc = pcap_setnonblock(net_pcap,1,errbuf); if (rc==0) { /* no errors! */ ne2000_log(".."); rc=pcap_getnonblock(net_pcap,errbuf); if(rc == 1) { ne2000_log("..!",rc); net_is_pcap=1; } else { ne2000_log("\tunable to set pcap into non-blocking mode!\nContinuining without pcap.\n"); net_is_pcap=0; } } /* end set nonblock */ else { ne2000_log("There was an unexpected error of [%s]\n\nexiting.\n",errbuf);net_is_pcap=0;} ne2000_log("\n"); break; case 1: ne2000_log("non blocking\n"); break; default: ne2000_log("this isn't right!!!\n"); net_is_pcap=0; break; } if (net_is_pcap) { struct bpf_program fp; char filter_exp[255]; ne2000_log("ne2000 Building packet filter..."); sprintf(filter_exp,"( ((ether dst ff:ff:ff:ff:ff:ff) or (ether dst %02x:%02x:%02x:%02x:%02x:%02x)) and not (ether src %02x:%02x:%02x:%02x:%02x:%02x) )", \ temp_mac[0], temp_mac[1], temp_mac[2], temp_mac[3], temp_mac[4], temp_mac[5],\ temp_mac[0], temp_mac[1], temp_mac[2], temp_mac[3], temp_mac[4], temp_mac[5]); /* I'm doing a MAC level filter so TCP/IP doesn't matter. */ if (pcap_compile(net_pcap, &fp, filter_exp, 0, 0xffffffff) == -1) { ne2000_log("\nne2000 Couldn't compile filter\n"); } else { ne2000_log("..."); if (pcap_setfilter(net_pcap, &fp) == -1) { ne2000_log("\nError installing pcap filter.\n"); } /* end of set_filter failure */ else { ne2000_log("...!\n"); } } ne2000_log("ne2000 Using filter\t[%s]\n",filter_exp); } else { pcap_device_available = 0; goto initialize_slirp; } ne2000_log("ne2000 net_is_pcap is %d and net_pcap is %x\n",net_is_pcap,net_pcap); } /* end pcap setup */ ne2000_log("ne2000 is_pcap %d\n", net_is_pcap); return ne2000; } void ne2000_close(void *p) { ne2000_t *ne2000 = (ne2000_t *)p; ne2000_io_remove(ne2000->base_address, ne2000); free(ne2000); if(!net_is_pcap) { QueueDestroy(slirpq); slirp_exit(0); net_slirp_inited=0; ne2000_log("ne2000 exiting slirp\n"); } else if (net_is_pcap && (net_pcap != NULL)) { pcap_close(net_pcap); ne2000_log("ne2000 closing pcap\n"); } ne2000_log("ne2000 close\n"); } static device_config_t ne2000_config[] = { { "addr", "Address", CONFIG_SELECTION, "", 0x300, { { "0x280", 0x280 }, { "0x300", 0x300 }, { "0x320", 0x320 }, { "0x340", 0x340 }, { "0x360", 0x360 }, { "0x380", 0x380 }, { "" } }, }, { "irq", "IRQ", CONFIG_SELECTION, "", 10, { { "IRQ 3", 3 }, { "IRQ 5", 5 }, { "IRQ 7", 7 }, { "IRQ 10", 10 }, { "IRQ 11", 11 }, { "" } }, }, { "net_type", "Network type", CONFIG_SELECTION, "", 0, { { "PCap", 0 }, { "SLiRP", 1 }, { "" } }, }, { "disable_netbios", "Disable network BIOS", CONFIG_BINARY, "", 0 }, { "", "", -1 } }; static device_config_t rtl8029as_config[] = { { "irq", "IRQ", CONFIG_SELECTION, "", 10, { { "IRQ 3", 3 }, { "IRQ 5", 5 }, { "IRQ 7", 7 }, { "IRQ 10", 10 }, { "IRQ 11", 11 }, { "" } }, }, { "net_type", "Network type", CONFIG_SELECTION, "", 0, { { "PCap", 0 }, { "SLiRP", 1 }, { "" } }, }, { "disable_netbios", "Disable network BIOS", CONFIG_BINARY, "", 0 }, { "", "", -1 } }; device_t ne2000_device = { "Novell NE2000", 0, ne2000_init, ne2000_close, NULL, NULL, NULL, NULL, ne2000_config }; device_t rtl8029as_device = { "Realtek RTL8029AS", 0, ne2000_init, ne2000_close, NULL, NULL, NULL, NULL, rtl8029as_config }; /* SLIRP stuff */ int slirp_can_output(void) { return net_slirp_inited; } void slirp_output (const unsigned char *pkt, int pkt_len) { struct queuepacket *p; p=(struct queuepacket *)malloc(sizeof(struct queuepacket)); p->len=pkt_len; memcpy(p->data,pkt,pkt_len); QueueEnter(slirpq,p); ne2000_log("ne2000 slirp_output %d @%d\n",pkt_len,p); } /* Instead of calling this and crashing some times or experencing jitter, this is called by the 60Hz clock which seems to do the job. */ void slirp_tic() { int ret2,nfds; struct timeval tv; fd_set rfds, wfds, xfds; int timeout; nfds=-1; if(net_slirp_inited) { FD_ZERO(&rfds); FD_ZERO(&wfds); FD_ZERO(&xfds); timeout=slirp_select_fill(&nfds,&rfds,&wfds,&xfds); /* this can crash */ if(timeout<0) { timeout=500; } tv.tv_sec=0; tv.tv_usec = timeout; /* basilisk default 10000 */ ret2 = select(nfds + 1, &rfds, &wfds, &xfds, &tv); if(ret2>=0) { slirp_select_poll(&rfds, &wfds, &xfds); } } /* end if slirp inited */ }