/************************************************************************** Etherboot - BOOTP/TFTP Bootstrap Program Skeleton NIC driver for Etherboot ***************************************************************************/ /* * 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 2, or (at * your option) any later version. */ /* to get some global routines like printf */ #include "etherboot.h" /* to get the interface to the body of the program */ #include "nic.h" /* Drag in support for whichever bus(es) we want for this NIC */ #include #include "isa.h" #include "eisa.h" #include "isapnp.h" #include "mca.h" /* * NIC specific static variables go here. Try to avoid using static * variables wherever possible. In particular, the I/O address can * always be accessed via nic->ioaddr. */ /* * If you have large static variables (e.g. transmit and receive * buffers), you should place them together in a single structure and * mark the structure as "shared". This enables this space to be * shared between drivers in multi-driver images, which can easily * reduce the runtime size by 50%. * */ #define SKEL_RX_BUFS 1 #define SKEL_TX_BUFS 1 #define SKEL_RX_BUFSIZE 0 #define SKEL_TX_BUFSIZE 0 struct skel_rx_desc {}; struct skel_tx_desc {}; struct { struct skel_rx_desc rxd[SKEL_RX_BUFS]; unsigned char rxb[SKEL_RX_BUFS][SKEL_RX_BUFSIZE]; struct skel_tx_desc txd[SKEL_TX_BUFS]; unsigned char txb[SKEL_TX_BUFS][SKEL_TX_BUFSIZE]; } skel_bufs __shared; /* * Don't forget to remove "__unused" from all the function parameters! * */ /************************************************************************** * CONNECT - Connect to the network ************************************************************************** */ static int skel_connect ( struct nic *nic __unused ) { /* * Connect to the network. For most NICs, this will probably * be a no-op. For wireless NICs, this should be the point at * which you attempt to join to an access point. * * Return 0 if the connection failed (e.g. no cable plugged * in), 1 for success. * */ return 1; } /************************************************************************** * TRANSMIT - Transmit a frame ************************************************************************** */ static void skel_transmit ( struct nic *nic __unused, const char *dest __unused, unsigned int type __unused, unsigned int size __unused, const char *packet __unused ) { /* Transmit packet to dest MAC address. You will need to * construct the link-layer header (dest MAC, source MAC, * type). */ /* unsigned int nstype = htons ( type ); memcpy ( , dest, ETH_ALEN ); memcpy ( + ETH_ALEN, nic->node_addr, ETH_ALEN ); memcpy ( + 2 * ETH_ALEN, &nstype, 2 ); memcpy ( + ETH_HLEN, data, size ); ( , size + ETH_HLEN ); */ } /************************************************************************** * POLL - Wait for a frame ************************************************************************** */ static int skel_poll ( struct nic *nic __unused, int retrieve __unused ) { /* Work out whether or not there's an ethernet packet ready to * read. Return 0 if not. */ /* if ( ! ) return 0; */ /* retrieve==0 indicates that we are just checking for the * presence of a packet but don't want to read it just yet. */ /* if ( ! retrieve ) return 1; */ /* Copy data to nic->packet. Data should include the * link-layer header (dest MAC, source MAC, type). * Store length of data in nic->packetlen. * Return true to indicate a packet has been read. */ /* nic->packetlen = ; memcpy ( nic->packet, , ); return 1; */ return 0; /* Remove this line once this method is implemented */ } /************************************************************************** * IRQ - handle interrupts ************************************************************************** */ static void skel_irq ( struct nic *nic __unused, irq_action_t action ) { /* This routine is somewhat optional. Etherboot itself * doesn't use interrupts, but they are required under some * circumstances when we're acting as a PXE stack. * * If you don't implement this routine, the only effect will * be that your driver cannot be used via Etherboot's UNDI * API. This won't affect programs that use only the UDP * portion of the PXE API, such as pxelinux. */ switch ( action ) { case DISABLE : case ENABLE : /* Set receive interrupt enabled/disabled state */ /* outb ( action == ENABLE ? IntrMaskEnabled : IntrMaskDisabled, nic->ioaddr + IntrMaskRegister ); */ break; case FORCE : /* Force NIC to generate a receive interrupt */ /* outb ( ForceInterrupt, nic->ioaddr + IntrForceRegister ); */ break; } } /************************************************************************** * OPERATIONS TABLE - Pointers to all the above methods ************************************************************************** */ static struct nic_operations skel_operations = { .connect = skel_connect, .transmit = skel_transmit, .poll = skel_poll, .irq = skel_irq, }; /************************************************************************** * PROBE - Look for an adapter * * You need to define a probe routine and a disable routine for each * bus type that your driver supports, together with tables that * enable Etherboot to identify that your driver should be used for a * particular device. * * Delete whichever of the following sections you don't need. For * example, most PCI devices will only need the PCI probing section; * ISAPnP, EISA, etc. can all be deleted. * * Some devices will need custom bus logic. The ISA 3c509 is a good * example of this; it has a contention-resolution mechanism that is * similar to ISAPnP, but not close enough to use the generic ISAPnP * code. Look at 3c509.c to see how it works. * ************************************************************************** */ /************************************************************************** * PCI PROBE and DISABLE ************************************************************************** */ static int skel_pci_probe ( struct nic *nic, struct pci_device *pci ) { pci_fill_nic ( nic, pci ); /* Test for physical presence of NIC */ /* if ( ! my_tests ) { DBG ( "Could not find NIC: my explanation\n" ); return 0; } */ /* point to NIC specific routines */ nic->nic_op = &skel_operations; return 1; } static void skel_pci_disable ( struct nic *nic __unused, struct pci_device *pci __unused ) { /* Reset the card to its initial state, disable DMA and * interrupts */ } static struct pci_id skel_pci_nics[] = { PCI_ROM ( 0x0000, 0x0000, "skel-pci", "Skeleton PCI Adapter" ), }; PCI_DRIVER ( skel_pci_driver, skel_pci_nics, PCI_NO_CLASS ); DRIVER ( "SKEL/PCI", nic_driver, pci_driver, skel_pci_driver, skel_pci_probe, skel_pci_disable ); /************************************************************************** * EISA PROBE and DISABLE ************************************************************************** */ static int skel_eisa_probe ( struct nic *nic, struct eisa_device *eisa ) { eisa_fill_nic ( nic, eisa ); enable_eisa_device ( eisa ); nic->irqno = 0; /* No standard way to get irq from EISA cards */ /* Test for physical presence of NIC */ /* if ( ! my_tests ) { DBG ( "Could not find NIC: my explanation\n" ); return 0; } */ /* point to NIC specific routines */ nic->nic_op = &skel_operations; return 1; } static void skel_eisa_disable ( struct nic *nic __unused, struct eisa_device *eisa ) { /* Reset the card to its initial state, disable DMA and * interrupts */ disable_eisa_device ( eisa ); } static struct eisa_id skel_eisa_nics[] = { { "Skeleton EISA Adapter", EISA_VENDOR('S','K','L'), 0x0000 }, }; EISA_DRIVER ( skel_eisa_driver, skel_eisa_nics ); DRIVER ( "SKEL/EISA", nic_driver, eisa_driver, skel_eisa_driver, skel_eisa_probe, skel_eisa_disable ); ISA_ROM ( "skel-eisa", "Skeleton EISA Adapter" ); /************************************************************************** * ISAPnP PROBE and DISABLE ************************************************************************** */ static int skel_isapnp_probe ( struct nic *nic, struct isapnp_device *isapnp ) { isapnp_fill_nic ( nic, isapnp ); activate_isapnp_device ( isapnp ); /* Test for physical presence of NIC */ /* if ( ! my_tests ) { DBG ( "Could not find NIC: my explanation\n" ); return 0; } */ /* point to NIC specific routines */ nic->nic_op = &skel_operations; return 1; } static void skel_isapnp_disable ( struct nic *nic __unused, struct isapnp_device *isapnp ) { /* Reset the card to its initial state, disable DMA and * interrupts */ deactivate_isapnp_device ( isapnp ); } static struct isapnp_id skel_isapnp_nics[] = { { "Skeleton ISAPnP Adapter", ISAPNP_VENDOR('S','K','L'), 0x0000 }, }; ISAPNP_DRIVER ( skel_isapnp_driver, skel_isapnp_nics ); DRIVER ( "SKEL/ISAPnP", nic_driver, isapnp_driver, skel_isapnp_driver, skel_isapnp_probe, skel_isapnp_disable ); ISA_ROM ( "skel-isapnp", "Skeleton ISAPnP Adapter" ); /************************************************************************** * MCA PROBE and DISABLE ************************************************************************** */ static int skel_mca_probe ( struct nic *nic, struct mca_device *mca ) { mca_fill_nic ( nic, mca ); /* MCA parameters are available in the mca->pos[] array */ /* nic->ioaddr = ( mca->pos[xxx] << 8 ) + mca->pos[yyy]; nic->irqno = mca->pos[zzz] & 0x0f; */ /* Test for physical presence of NIC */ /* if ( ! my_tests ) { DBG ( "Could not find NIC: my explanation\n" ); return 0; } */ /* point to NIC specific routines */ nic->nic_op = &skel_operations; return 1; } static void skel_mca_disable ( struct nic *nic __unused, struct mca_device *mca __unused ) { /* Reset the card to its initial state, disable DMA and * interrupts */ } static struct mca_id skel_mca_nics[] = { { "Skeleton MCA Adapter", 0x0000 }, }; MCA_DRIVER ( skel_mca_driver, skel_mca_nics ); DRIVER ( "SKEL/MCA", nic_driver, mca_driver, skel_mca_driver, skel_mca_probe, skel_mca_disable ); ISA_ROM ( "skel-mca", "Skeleton MCA Adapter" ); /************************************************************************** * ISA PROBE and DISABLE * * The "classical" ISA probe is split into two stages: trying a list * of I/O addresses to see if there's anything listening, and then * using that I/O address to fill in the information in the nic * structure. * * The list of probe addresses defined in skel_isa_probe_addrs[] will * be passed to skel_isa_probe_addr(). If skel_isa_probe_addr() * returns true, a struct isa_device will be created with isa->ioaddr * set to the working I/O address, and skel_isa_probe() will be * called. * * There is a standard mechanism for overriding the probe address list * using ISA_PROBE_ADDRS. Do not implement any custom code to * override the probe address list. * ************************************************************************** */ static int skel_isa_probe_addr ( isa_probe_addr_t ioaddr __unused ) { return 0; } static int skel_isa_probe ( struct nic *nic, struct isa_device *isa ) { isa_fill_nic ( nic, isa ); nic->irqno = 0; /* No standard way to get IRQ for ISA */ /* Test for physical presence of NIC */ /* if ( ! my_tests ) { DBG ( "Could not find NIC: my explanation\n" ); return 0; } */ /* point to NIC specific routines */ nic->nic_op = &skel_operations; return 1; } static void skel_isa_disable ( struct nic *nic __unused, struct isa_device *isa __unused ) { /* Reset the card to its initial state, disable DMA and * interrupts */ } static isa_probe_addr_t skel_isa_probe_addrs[] = { /* 0x200, 0x240, */ }; ISA_DRIVER ( skel_isa_driver, skel_isa_probe_addrs, skel_isa_probe_addr, ISA_VENDOR('S','K','L'), 0x0000 ); DRIVER ( "SKEL/ISA", nic_driver, isa_driver, skel_isa_driver, skel_isa_probe, skel_isa_disable ); ISA_ROM ( "skel-isa", "Skeleton ISA Adapter" );