/** @file * * * */ /* * Copyright (C) 2004 Michael Brown . * * 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 of the * License, or 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, write to the Free Software * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. */ #include "dev.h" #include "pxe.h" struct net_device *pxe_netdev = NULL; #if 0 /* Global pointer to currently installed PXE stack */ pxe_stack_t *pxe_stack = NULL; /* Various startup/shutdown routines. The startup/shutdown call * sequence is incredibly badly defined in the Intel PXE spec, for * example: * * PXENV_UNDI_INITIALIZE says that the parameters used to initialize * the adaptor should be those supplied to the most recent * PXENV_UNDI_STARTUP call. PXENV_UNDI_STARTUP takes no parameters. * * PXENV_UNDI_CLEANUP says that the rest of the API will not be * available after making this call. Figure 3-3 ("Early UNDI API * usage") shows a call to PXENV_UNDI_CLEANUP being followed by a * call to the supposedly now unavailable PXENV_STOP_UNDI. * * PXENV_UNLOAD_BASE_STACK talks about freeing up the memory * occupied by the PXE stack. Figure 4-3 ("PXE IPL") shows a call * to PXENV_STOP_UNDI being made after the call to * PXENV_UNLOAD_BASE_STACK, by which time the entire PXE stack * should have been freed (and, potentially, zeroed). * * Nothing, anywhere, seems to mention who's responsible for freeing * up the base memory allocated for the stack segment. It's not * even clear whether or not this is expected to be in free base * memory rather than claimed base memory. * * Consequently, we adopt a rather defensive strategy, designed to * work with any conceivable sequence of initialisation or shutdown * calls. We have only two things that we care about: * * 1. Have we hooked INT 1A and INT 15,E820(etc.)? * 2. Is the NIC initialised? * * The NIC should never be initialised without the vectors being * hooked, similarly the vectors should never be unhooked with the NIC * still initialised. We do, however, want to be able to have the * vectors hooked with the NIC shutdown. We therefore have three * possible states: * * 1. Ready to unload: interrupts unhooked, NIC shutdown. * 2. Midway: interrupts hooked, NIC shutdown. * 3. Fully ready: interrupts hooked, NIC initialised. * * We provide the three states CAN_UNLOAD, MIDWAY and READY to define * these, and the call pxe_ensure_state() to ensure that the stack is * in the specified state. All our PXE API call implementations * should use this call to ensure that the state is as required for * that PXE API call. This enables us to cope with whatever the * end-user's interpretation of the PXE spec may be. It even allows * for someone calling e.g. PXENV_START_UNDI followed by * PXENV_UDP_WRITE, without bothering with any of the intervening * calls. * * pxe_ensure_state() returns 1 for success, 0 for failure. In the * event of failure (which can arise from e.g. asking for state READY * when we don't know where our NIC is), the error code * PXENV_STATUS_UNDI_INVALID_STATE should be returned to the user. * The macros ENSURE_XXX() can be used to achieve this without lots of * duplicated code. */ /* pxe_[un]hook_stack are architecture-specific and provided in * pxe_callbacks.c */ int pxe_initialise_nic ( void ) { if ( pxe_stack->state >= READY ) return 1; #warning "device probing mechanism has completely changed" #if 0 /* Check if NIC is initialised. dev.disable is set to 0 * when disable() is called, so we use this. */ if ( dev.disable ) { /* NIC may have been initialised independently * (e.g. when we set up the stack prior to calling the * NBP). */ pxe_stack->state = READY; return 1; } /* If we already have a NIC defined, reuse that one with * PROBE_AWAKE. If one was specifed via PXENV_START_UNDI, try * that one first. Otherwise, set PROBE_FIRST. */ if ( dev.state.pci.dev.use_specified == 1 ) { dev.how_probe = PROBE_NEXT; DBG ( " initialising NIC specified via START_UNDI" ); } else if ( dev.state.pci.dev.driver ) { DBG ( " reinitialising NIC" ); dev.how_probe = PROBE_AWAKE; } else { DBG ( " probing for any NIC" ); dev.how_probe = PROBE_FIRST; } /* Call probe routine to bring up the NIC */ if ( eth_probe ( &dev ) != PROBE_WORKED ) { DBG ( " failed" ); return 0; } #endif pxe_stack->state = READY; return 1; } int pxe_shutdown_nic ( void ) { if ( pxe_stack->state <= MIDWAY ) return 1; eth_irq ( DISABLE ); disable ( &dev ); pxe_stack->state = MIDWAY; return 1; } int ensure_pxe_state ( pxe_stack_state_t wanted ) { int success = 1; if ( ! pxe_stack ) return 0; if ( wanted >= MIDWAY ) success = success & hook_pxe_stack(); if ( wanted > MIDWAY ) { success = success & pxe_initialise_nic(); } else { success = success & pxe_shutdown_nic(); } if ( wanted < MIDWAY ) success = success & unhook_pxe_stack(); return success; } #endif