gpxe/src/arch/i386/image/multiboot.c - platform/external/syslinux - Git at Google

 /*
  * Copyright (C) 2007 Michael Brown <mbrown@fensystems.co.uk>.
  *
  * 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.
  */

 FILE_LICENCE ( GPL2_OR_LATER );

 /**
  * @file
  *
  * Multiboot image format
  *
  */

 #include <stdio.h>
 #include <errno.h>
 #include <assert.h>
 #include <realmode.h>
 #include <multiboot.h>
 #include <gpxe/uaccess.h>
 #include <gpxe/image.h>
 #include <gpxe/segment.h>
 #include <gpxe/memmap.h>
 #include <gpxe/elf.h>
 #include <gpxe/init.h>
 #include <gpxe/features.h>

 FEATURE ( FEATURE_IMAGE, "Multiboot", DHCP_EB_FEATURE_MULTIBOOT, 1 );

 struct image_type multiboot_image_type __image_type ( PROBE_MULTIBOOT );

 /**
  * Maximum number of modules we will allow for
  *
  * If this has bitten you: sorry.  I did have a perfect scheme with a
  * dynamically allocated list of modules on the protected-mode stack,
  * but it was incompatible with some broken OSes that can only access
  * low memory at boot time (even though we kindly set up 4GB flat
  * physical addressing as per the multiboot specification.
  *
  */
 #define MAX_MODULES 8

 /**
  * Maximum combined length of command lines
  *
  * Again; sorry.  Some broken OSes zero out any non-base memory that
  * isn't part of the loaded module set, so we can't just use
  * virt_to_phys(cmdline) to point to the command lines, even though
  * this would comply with the Multiboot spec.
  */
 #define MB_MAX_CMDLINE 512

 /** Multiboot flags that we support */
 #define MB_SUPPORTED_FLAGS ( MB_FLAG_PGALIGN | MB_FLAG_MEMMAP | \
 			     MB_FLAG_VIDMODE | MB_FLAG_RAW )

 /** Compulsory feature multiboot flags */
 #define MB_COMPULSORY_FLAGS 0x0000ffff

 /** Optional feature multiboot flags */
 #define MB_OPTIONAL_FLAGS 0xffff0000

 /**
  * Multiboot flags that we don't support
  *
  * We only care about the compulsory feature flags (bits 0-15); we are
  * allowed to ignore the optional feature flags.
  */
 #define MB_UNSUPPORTED_FLAGS ( MB_COMPULSORY_FLAGS & ~MB_SUPPORTED_FLAGS )

 /** A multiboot header descriptor */
 struct multiboot_header_info {
 	/** The actual multiboot header */
 	struct multiboot_header mb;
 	/** Offset of header within the multiboot image */
 	size_t offset;
 };

 /** Multiboot module command lines */
 static char __bss16_array ( mb_cmdlines, [MB_MAX_CMDLINE] );
 #define mb_cmdlines __use_data16 ( mb_cmdlines )

 /** Offset within module command lines */
 static unsigned int mb_cmdline_offset;

 /**
  * Build multiboot memory map
  *
  * @v image		Multiboot image
  * @v mbinfo		Multiboot information structure
  * @v mbmemmap		Multiboot memory map
  * @v limit		Maxmimum number of memory map entries
  */
 static void multiboot_build_memmap ( struct image *image,
 				     struct multiboot_info *mbinfo,
 				     struct multiboot_memory_map *mbmemmap,
 				     unsigned int limit ) {
 	struct memory_map memmap;
 	unsigned int i;

 	/* Get memory map */
 	get_memmap ( &memmap );

 	/* Translate into multiboot format */
 	memset ( mbmemmap, 0, sizeof ( *mbmemmap ) );
 	for ( i = 0 ; i < memmap.count ; i++ ) {
 		if ( i >= limit ) {
 			DBGC ( image, "MULTIBOOT %p limit of %d memmap "
 			       "entries reached\n", image, limit );
 			break;
 		}
 		mbmemmap[i].size = ( sizeof ( mbmemmap[i] ) -
 				     sizeof ( mbmemmap[i].size ) );
 		mbmemmap[i].base_addr = memmap.regions[i].start;
 		mbmemmap[i].length = ( memmap.regions[i].end -
 				       memmap.regions[i].start );
 		mbmemmap[i].type = MBMEM_RAM;
 		mbinfo->mmap_length += sizeof ( mbmemmap[i] );
 		if ( memmap.regions[i].start == 0 )
 			mbinfo->mem_lower = ( memmap.regions[i].end / 1024 );
 		if ( memmap.regions[i].start == 0x100000 )
 			mbinfo->mem_upper = ( ( memmap.regions[i].end -
 						0x100000 ) / 1024 );
 	}
 }

 /**
  * Add command line in base memory
  *
  * @v imgname		Image name
  * @v cmdline		Command line
  * @ret physaddr	Physical address of command line
  */
 physaddr_t multiboot_add_cmdline ( const char *imgname, const char *cmdline ) {
 	char *mb_cmdline;

 	if ( ! cmdline )
 		cmdline = "";

 	/* Copy command line to base memory buffer */
 	mb_cmdline = ( mb_cmdlines + mb_cmdline_offset );
 	mb_cmdline_offset +=
 		( snprintf ( mb_cmdline,
 			     ( sizeof ( mb_cmdlines ) - mb_cmdline_offset ),
 			     "%s %s", imgname, cmdline ) + 1 );

 	/* Truncate to terminating NUL in buffer if necessary */
 	if ( mb_cmdline_offset > sizeof ( mb_cmdlines ) )
 		mb_cmdline_offset = ( sizeof ( mb_cmdlines ) - 1 );

 	return virt_to_phys ( mb_cmdline );
 }

 /**
  * Build multiboot module list
  *
  * @v image		Multiboot image
  * @v modules		Module list to fill, or NULL
  * @ret count		Number of modules
  */
 static unsigned int
 multiboot_build_module_list ( struct image *image,
 			      struct multiboot_module *modules,
 			      unsigned int limit ) {
 	struct image *module_image;
 	struct multiboot_module *module;
 	unsigned int count = 0;
 	unsigned int insert;
 	physaddr_t start;
 	physaddr_t end;
 	unsigned int i;

 	/* Add each image as a multiboot module */
 	for_each_image ( module_image ) {

 		if ( count >= limit ) {
 			DBGC ( image, "MULTIBOOT %p limit of %d modules "
 			       "reached\n", image, limit );
 			break;
 		}

 		/* Do not include kernel image itself as a module */
 		if ( module_image == image )
 			continue;

 		/* At least some OSes expect the multiboot modules to
 		 * be in ascending order, so we have to support it.
 		 */
 		start = user_to_phys ( module_image->data, 0 );
 		end = user_to_phys ( module_image->data, module_image->len );
 		for ( insert = 0 ; insert < count ; insert++ ) {
 			if ( start < modules[insert].mod_start )
 				break;
 		}
 		module = &modules[insert];
 		memmove ( ( module + 1 ), module,
 			  ( ( count - insert ) * sizeof ( *module ) ) );
 		module->mod_start = start;
 		module->mod_end = end;
 		module->string = multiboot_add_cmdline ( module_image->name,
 						       module_image->cmdline );
 		module->reserved = 0;

 		/* We promise to page-align modules */
 		assert ( ( module->mod_start & 0xfff ) == 0 );

 		count++;
 	}

 	/* Dump module configuration */
 	for ( i = 0 ; i < count ; i++ ) {
 		DBGC ( image, "MULTIBOOT %p module %d is [%x,%x)\n",
 		       image, i, modules[i].mod_start,
 		       modules[i].mod_end );
 	}

 	return count;
 }

 /**
  * The multiboot information structure
  *
  * Kept in base memory because some OSes won't find it elsewhere,
  * along with the other structures belonging to the Multiboot
  * information table.
  */
 static struct multiboot_info __bss16 ( mbinfo );
 #define mbinfo __use_data16 ( mbinfo )

 /** The multiboot bootloader name */
 static char __data16_array ( mb_bootloader_name, [] ) = "gPXE " VERSION;
 #define mb_bootloader_name __use_data16 ( mb_bootloader_name )

 /** The multiboot memory map */
 static struct multiboot_memory_map
 	__bss16_array ( mbmemmap, [MAX_MEMORY_REGIONS] );
 #define mbmemmap __use_data16 ( mbmemmap )

 /** The multiboot module list */
 static struct multiboot_module __bss16_array ( mbmodules, [MAX_MODULES] );
 #define mbmodules __use_data16 ( mbmodules )

 /**
  * Execute multiboot image
  *
  * @v image		Multiboot image
  * @ret rc		Return status code
  */
 static int multiboot_exec ( struct image *image ) {
 	physaddr_t entry = image->priv.phys;

 	/* Populate multiboot information structure */
 	memset ( &mbinfo, 0, sizeof ( mbinfo ) );
 	mbinfo.flags = ( MBI_FLAG_LOADER | MBI_FLAG_MEM | MBI_FLAG_MMAP |
 			 MBI_FLAG_CMDLINE | MBI_FLAG_MODS );
 	mb_cmdline_offset = 0;
 	mbinfo.cmdline = multiboot_add_cmdline ( image->name, image->cmdline );
 	mbinfo.mods_count = multiboot_build_module_list ( image, mbmodules,
 				( sizeof(mbmodules) / sizeof(mbmodules[0]) ) );
 	mbinfo.mods_addr = virt_to_phys ( mbmodules );
 	mbinfo.mmap_addr = virt_to_phys ( mbmemmap );
 	mbinfo.boot_loader_name = virt_to_phys ( mb_bootloader_name );

 	/* Multiboot images may not return and have no callback
 	 * interface, so shut everything down prior to booting the OS.
 	 */
 	shutdown ( SHUTDOWN_BOOT );

 	/* Build memory map after unhiding bootloader memory regions as part of
 	 * shutting everything down.
 	 */
 	multiboot_build_memmap ( image, &mbinfo, mbmemmap,
 				 ( sizeof(mbmemmap) / sizeof(mbmemmap[0]) ) );

 	/* Jump to OS with flat physical addressing */
 	DBGC ( image, "MULTIBOOT %p starting execution at %lx\n",
 	       image, entry );
 	__asm__ __volatile__ ( PHYS_CODE ( "pushl %%ebp\n\t"
 					   "call *%%edi\n\t"
 					   "popl %%ebp\n\t" )
 			       : : "a" ( MULTIBOOT_BOOTLOADER_MAGIC ),
 			           "b" ( virt_to_phys ( &mbinfo ) ),
 			           "D" ( entry )
 			       : "ecx", "edx", "esi", "memory" );

 	DBGC ( image, "MULTIBOOT %p returned\n", image );

 	/* It isn't safe to continue after calling shutdown() */
 	while ( 1 ) {}

 	return -ECANCELED;  /* -EIMPOSSIBLE, anyone? */
 }

 /**
  * Find multiboot header
  *
  * @v image		Multiboot file
  * @v hdr		Multiboot header descriptor to fill in
  * @ret rc		Return status code
  */
 static int multiboot_find_header ( struct image *image,
 				   struct multiboot_header_info *hdr ) {
 	uint32_t buf[64];
 	size_t offset;
 	unsigned int buf_idx;
 	uint32_t checksum;

 	/* Scan through first 8kB of image file 256 bytes at a time.
 	 * (Use the buffering to avoid the overhead of a
 	 * copy_from_user() for every dword.)
 	 */
 	for ( offset = 0 ; offset < 8192 ; offset += sizeof ( buf[0] ) ) {
 		/* Check for end of image */
 		if ( offset > image->len )
 			break;
 		/* Refill buffer if applicable */
 		buf_idx = ( ( offset % sizeof ( buf ) ) / sizeof ( buf[0] ) );
 		if ( buf_idx == 0 ) {
 			copy_from_user ( buf, image->data, offset,
 					 sizeof ( buf ) );
 		}
 		/* Check signature */
 		if ( buf[buf_idx] != MULTIBOOT_HEADER_MAGIC )
 			continue;
 		/* Copy header and verify checksum */
 		copy_from_user ( &hdr->mb, image->data, offset,
 				 sizeof ( hdr->mb ) );
 		checksum = ( hdr->mb.magic + hdr->mb.flags +
 			     hdr->mb.checksum );
 		if ( checksum != 0 )
 			continue;
 		/* Record offset of multiboot header and return */
 		hdr->offset = offset;
 		return 0;
 	}

 	/* No multiboot header found */
 	return -ENOEXEC;
 }

 /**
  * Load raw multiboot image into memory
  *
  * @v image		Multiboot file
  * @v hdr		Multiboot header descriptor
  * @ret rc		Return status code
  */
 static int multiboot_load_raw ( struct image *image,
 				struct multiboot_header_info *hdr ) {
 	size_t offset;
 	size_t filesz;
 	size_t memsz;
 	userptr_t buffer;
 	int rc;

 	/* Sanity check */
 	if ( ! ( hdr->mb.flags & MB_FLAG_RAW ) ) {
 		DBGC ( image, "MULTIBOOT %p is not flagged as a raw image\n",
 		       image );
 		return -EINVAL;
 	}

 	/* Verify and prepare segment */
 	offset = ( hdr->offset - hdr->mb.header_addr + hdr->mb.load_addr );
 	filesz = ( hdr->mb.load_end_addr ?
 		   ( hdr->mb.load_end_addr - hdr->mb.load_addr ) :
 		   ( image->len - offset ) );
 	memsz = ( hdr->mb.bss_end_addr ?
 		  ( hdr->mb.bss_end_addr - hdr->mb.load_addr ) : filesz );
 	buffer = phys_to_user ( hdr->mb.load_addr );
 	if ( ( rc = prep_segment ( buffer, filesz, memsz ) ) != 0 ) {
 		DBGC ( image, "MULTIBOOT %p could not prepare segment: %s\n",
 		       image, strerror ( rc ) );
 		return rc;
 	}

 	/* Copy image to segment */
 	memcpy_user ( buffer, 0, image->data, offset, filesz );

 	/* Record execution entry point in image private data field */
 	image->priv.phys = hdr->mb.entry_addr;

 	return 0;
 }

 /**
  * Load ELF multiboot image into memory
  *
  * @v image		Multiboot file
  * @ret rc		Return status code
  */
 static int multiboot_load_elf ( struct image *image ) {
 	int rc;

 	/* Load ELF image*/
 	if ( ( rc = elf_load ( image ) ) != 0 ) {
 		DBGC ( image, "MULTIBOOT %p ELF image failed to load: %s\n",
 		       image, strerror ( rc ) );
 		return rc;
 	}

 	return 0;
 }

 /**
  * Load multiboot image into memory
  *
  * @v image		Multiboot file
  * @ret rc		Return status code
  */
 static int multiboot_load ( struct image *image ) {
 	struct multiboot_header_info hdr;
 	int rc;

 	/* Locate multiboot header, if present */
 	if ( ( rc = multiboot_find_header ( image, &hdr ) ) != 0 ) {
 		DBGC ( image, "MULTIBOOT %p has no multiboot header\n",
 		       image );
 		return rc;
 	}
 	DBGC ( image, "MULTIBOOT %p found header with flags %08x\n",
 	       image, hdr.mb.flags );

 	/* This is a multiboot image, valid or otherwise */
 	if ( ! image->type )
 		image->type = &multiboot_image_type;

 	/* Abort if we detect flags that we cannot support */
 	if ( hdr.mb.flags & MB_UNSUPPORTED_FLAGS ) {
 		DBGC ( image, "MULTIBOOT %p flags %08x not supported\n",
 		       image, ( hdr.mb.flags & MB_UNSUPPORTED_FLAGS ) );
 		return -ENOTSUP;
 	}

 	/* There is technically a bit MB_FLAG_RAW to indicate whether
 	 * this is an ELF or a raw image.  In practice, grub will use
 	 * the ELF header if present, and Solaris relies on this
 	 * behaviour.
 	 */
 	if ( ( ( rc = multiboot_load_elf ( image ) ) != 0 ) &&
 	     ( ( rc = multiboot_load_raw ( image, &hdr ) ) != 0 ) )
 		return rc;

 	return 0;
 }

 /** Multiboot image type */
 struct image_type multiboot_image_type __image_type ( PROBE_MULTIBOOT ) = {
 	.name = "Multiboot",
 	.load = multiboot_load,
 	.exec = multiboot_exec,
 };
	/*
	* Copyright (C) 2007 Michael Brown <mbrown@fensystems.co.uk>.
	*
	* 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.
	*/

	FILE_LICENCE ( GPL2_OR_LATER );

	/**
	* @file
	*
	* Multiboot image format
	*
	*/

	#include <stdio.h>
	#include <errno.h>
	#include <assert.h>
	#include <realmode.h>
	#include <multiboot.h>
	#include <gpxe/uaccess.h>
	#include <gpxe/image.h>
	#include <gpxe/segment.h>
	#include <gpxe/memmap.h>
	#include <gpxe/elf.h>
	#include <gpxe/init.h>
	#include <gpxe/features.h>

	FEATURE ( FEATURE_IMAGE, "Multiboot", DHCP_EB_FEATURE_MULTIBOOT, 1 );

	struct image_type multiboot_image_type __image_type ( PROBE_MULTIBOOT );

	/**
	* Maximum number of modules we will allow for
	*
	* If this has bitten you: sorry. I did have a perfect scheme with a
	* dynamically allocated list of modules on the protected-mode stack,
	* but it was incompatible with some broken OSes that can only access
	* low memory at boot time (even though we kindly set up 4GB flat
	* physical addressing as per the multiboot specification.
	*
	*/
	#define MAX_MODULES 8

	/**
	* Maximum combined length of command lines
	*
	* Again; sorry. Some broken OSes zero out any non-base memory that
	* isn't part of the loaded module set, so we can't just use
	* virt_to_phys(cmdline) to point to the command lines, even though
	* this would comply with the Multiboot spec.
	*/
	#define MB_MAX_CMDLINE 512

	/** Multiboot flags that we support */
	#define MB_SUPPORTED_FLAGS ( MB_FLAG_PGALIGN \| MB_FLAG_MEMMAP \| \
	MB_FLAG_VIDMODE \| MB_FLAG_RAW )

	/** Compulsory feature multiboot flags */
	#define MB_COMPULSORY_FLAGS 0x0000ffff

	/** Optional feature multiboot flags */
	#define MB_OPTIONAL_FLAGS 0xffff0000

	/**
	* Multiboot flags that we don't support
	*
	* We only care about the compulsory feature flags (bits 0-15); we are
	* allowed to ignore the optional feature flags.
	*/
	#define MB_UNSUPPORTED_FLAGS ( MB_COMPULSORY_FLAGS & ~MB_SUPPORTED_FLAGS )

	/** A multiboot header descriptor */
	struct multiboot_header_info {
	/** The actual multiboot header */
	struct multiboot_header mb;
	/** Offset of header within the multiboot image */
	size_t offset;
	};

	/** Multiboot module command lines */
	static char __bss16_array ( mb_cmdlines, [MB_MAX_CMDLINE] );
	#define mb_cmdlines __use_data16 ( mb_cmdlines )

	/** Offset within module command lines */
	static unsigned int mb_cmdline_offset;

	/**
	* Build multiboot memory map
	*
	* @v image Multiboot image
	* @v mbinfo Multiboot information structure
	* @v mbmemmap Multiboot memory map
	* @v limit Maxmimum number of memory map entries
	*/
	static void multiboot_build_memmap ( struct image *image,
	struct multiboot_info *mbinfo,
	struct multiboot_memory_map *mbmemmap,
	unsigned int limit ) {
	struct memory_map memmap;
	unsigned int i;

	/* Get memory map */
	get_memmap ( &memmap );

	/* Translate into multiboot format */
	memset ( mbmemmap, 0, sizeof ( *mbmemmap ) );
	for ( i = 0 ; i < memmap.count ; i++ ) {
	if ( i >= limit ) {
	DBGC ( image, "MULTIBOOT %p limit of %d memmap "
	"entries reached\n", image, limit );
	break;
	}
	mbmemmap[i].size = ( sizeof ( mbmemmap[i] ) -
	sizeof ( mbmemmap[i].size ) );
	mbmemmap[i].base_addr = memmap.regions[i].start;
	mbmemmap[i].length = ( memmap.regions[i].end -
	memmap.regions[i].start );
	mbmemmap[i].type = MBMEM_RAM;
	mbinfo->mmap_length += sizeof ( mbmemmap[i] );
	if ( memmap.regions[i].start == 0 )
	mbinfo->mem_lower = ( memmap.regions[i].end / 1024 );
	if ( memmap.regions[i].start == 0x100000 )
	mbinfo->mem_upper = ( ( memmap.regions[i].end -
	0x100000 ) / 1024 );
	}
	}

	/**
	* Add command line in base memory
	*
	* @v imgname Image name
	* @v cmdline Command line
	* @ret physaddr Physical address of command line
	*/
	physaddr_t multiboot_add_cmdline ( const char imgname, const char cmdline ) {
	char *mb_cmdline;

	if ( ! cmdline )
	cmdline = "";

	/* Copy command line to base memory buffer */
	mb_cmdline = ( mb_cmdlines + mb_cmdline_offset );
	mb_cmdline_offset +=
	( snprintf ( mb_cmdline,
	( sizeof ( mb_cmdlines ) - mb_cmdline_offset ),
	"%s %s", imgname, cmdline ) + 1 );

	/* Truncate to terminating NUL in buffer if necessary */
	if ( mb_cmdline_offset > sizeof ( mb_cmdlines ) )
	mb_cmdline_offset = ( sizeof ( mb_cmdlines ) - 1 );

	return virt_to_phys ( mb_cmdline );
	}

	/**
	* Build multiboot module list
	*
	* @v image Multiboot image
	* @v modules Module list to fill, or NULL
	* @ret count Number of modules
	*/
	static unsigned int
	multiboot_build_module_list ( struct image *image,
	struct multiboot_module *modules,
	unsigned int limit ) {
	struct image *module_image;
	struct multiboot_module *module;
	unsigned int count = 0;
	unsigned int insert;
	physaddr_t start;
	physaddr_t end;
	unsigned int i;

	/* Add each image as a multiboot module */
	for_each_image ( module_image ) {

	if ( count >= limit ) {
	DBGC ( image, "MULTIBOOT %p limit of %d modules "
	"reached\n", image, limit );
	break;
	}

	/* Do not include kernel image itself as a module */
	if ( module_image == image )
	continue;

	/* At least some OSes expect the multiboot modules to
	* be in ascending order, so we have to support it.
	*/
	start = user_to_phys ( module_image->data, 0 );
	end = user_to_phys ( module_image->data, module_image->len );
	for ( insert = 0 ; insert < count ; insert++ ) {
	if ( start < modules[insert].mod_start )
	break;
	}
	module = &modules[insert];
	memmove ( ( module + 1 ), module,
	( ( count - insert ) * sizeof ( *module ) ) );
	module->mod_start = start;
	module->mod_end = end;
	module->string = multiboot_add_cmdline ( module_image->name,
	module_image->cmdline );
	module->reserved = 0;

	/* We promise to page-align modules */
	assert ( ( module->mod_start & 0xfff ) == 0 );

	count++;
	}

	/* Dump module configuration */
	for ( i = 0 ; i < count ; i++ ) {
	DBGC ( image, "MULTIBOOT %p module %d is [%x,%x)\n",
	image, i, modules[i].mod_start,
	modules[i].mod_end );
	}

	return count;
	}

	/**
	* The multiboot information structure
	*
	* Kept in base memory because some OSes won't find it elsewhere,
	* along with the other structures belonging to the Multiboot
	* information table.
	*/
	static struct multiboot_info __bss16 ( mbinfo );
	#define mbinfo __use_data16 ( mbinfo )

	/** The multiboot bootloader name */
	static char __data16_array ( mb_bootloader_name, [] ) = "gPXE " VERSION;
	#define mb_bootloader_name __use_data16 ( mb_bootloader_name )

	/** The multiboot memory map */
	static struct multiboot_memory_map
	__bss16_array ( mbmemmap, [MAX_MEMORY_REGIONS] );
	#define mbmemmap __use_data16 ( mbmemmap )

	/** The multiboot module list */
	static struct multiboot_module __bss16_array ( mbmodules, [MAX_MODULES] );
	#define mbmodules __use_data16 ( mbmodules )

	/**
	* Execute multiboot image
	*
	* @v image Multiboot image
	* @ret rc Return status code
	*/
	static int multiboot_exec ( struct image *image ) {
	physaddr_t entry = image->priv.phys;

	/* Populate multiboot information structure */
	memset ( &mbinfo, 0, sizeof ( mbinfo ) );
	mbinfo.flags = ( MBI_FLAG_LOADER \| MBI_FLAG_MEM \| MBI_FLAG_MMAP \|
	MBI_FLAG_CMDLINE \| MBI_FLAG_MODS );
	mb_cmdline_offset = 0;
	mbinfo.cmdline = multiboot_add_cmdline ( image->name, image->cmdline );
	mbinfo.mods_count = multiboot_build_module_list ( image, mbmodules,
	( sizeof(mbmodules) / sizeof(mbmodules[0]) ) );
	mbinfo.mods_addr = virt_to_phys ( mbmodules );
	mbinfo.mmap_addr = virt_to_phys ( mbmemmap );
	mbinfo.boot_loader_name = virt_to_phys ( mb_bootloader_name );

	/* Multiboot images may not return and have no callback
	* interface, so shut everything down prior to booting the OS.
	*/
	shutdown ( SHUTDOWN_BOOT );

	/* Build memory map after unhiding bootloader memory regions as part of
	* shutting everything down.
	*/
	multiboot_build_memmap ( image, &mbinfo, mbmemmap,
	( sizeof(mbmemmap) / sizeof(mbmemmap[0]) ) );

	/* Jump to OS with flat physical addressing */
	DBGC ( image, "MULTIBOOT %p starting execution at %lx\n",
	image, entry );
	__asm__ __volatile__ ( PHYS_CODE ( "pushl %%ebp\n\t"
	"call *%%edi\n\t"
	"popl %%ebp\n\t" )
	: : "a" ( MULTIBOOT_BOOTLOADER_MAGIC ),
	"b" ( virt_to_phys ( &mbinfo ) ),
	"D" ( entry )
	: "ecx", "edx", "esi", "memory" );

	DBGC ( image, "MULTIBOOT %p returned\n", image );

	/* It isn't safe to continue after calling shutdown() */
	while ( 1 ) {}

	return -ECANCELED; /* -EIMPOSSIBLE, anyone? */
	}

	/**
	* Find multiboot header
	*
	* @v image Multiboot file
	* @v hdr Multiboot header descriptor to fill in
	* @ret rc Return status code
	*/
	static int multiboot_find_header ( struct image *image,
	struct multiboot_header_info *hdr ) {
	uint32_t buf[64];
	size_t offset;
	unsigned int buf_idx;
	uint32_t checksum;

	/* Scan through first 8kB of image file 256 bytes at a time.
	* (Use the buffering to avoid the overhead of a
	* copy_from_user() for every dword.)
	*/
	for ( offset = 0 ; offset < 8192 ; offset += sizeof ( buf[0] ) ) {
	/* Check for end of image */
	if ( offset > image->len )
	break;
	/* Refill buffer if applicable */
	buf_idx = ( ( offset % sizeof ( buf ) ) / sizeof ( buf[0] ) );
	if ( buf_idx == 0 ) {
	copy_from_user ( buf, image->data, offset,
	sizeof ( buf ) );
	}
	/* Check signature */
	if ( buf[buf_idx] != MULTIBOOT_HEADER_MAGIC )
	continue;
	/* Copy header and verify checksum */
	copy_from_user ( &hdr->mb, image->data, offset,
	sizeof ( hdr->mb ) );
	checksum = ( hdr->mb.magic + hdr->mb.flags +
	hdr->mb.checksum );
	if ( checksum != 0 )
	continue;
	/* Record offset of multiboot header and return */
	hdr->offset = offset;
	return 0;
	}

	/* No multiboot header found */
	return -ENOEXEC;
	}

	/**
	* Load raw multiboot image into memory
	*
	* @v image Multiboot file
	* @v hdr Multiboot header descriptor
	* @ret rc Return status code
	*/
	static int multiboot_load_raw ( struct image *image,
	struct multiboot_header_info *hdr ) {
	size_t offset;
	size_t filesz;
	size_t memsz;
	userptr_t buffer;
	int rc;

	/* Sanity check */
	if ( ! ( hdr->mb.flags & MB_FLAG_RAW ) ) {
	DBGC ( image, "MULTIBOOT %p is not flagged as a raw image\n",
	image );
	return -EINVAL;
	}

	/* Verify and prepare segment */
	offset = ( hdr->offset - hdr->mb.header_addr + hdr->mb.load_addr );
	filesz = ( hdr->mb.load_end_addr ?
	( hdr->mb.load_end_addr - hdr->mb.load_addr ) :
	( image->len - offset ) );
	memsz = ( hdr->mb.bss_end_addr ?
	( hdr->mb.bss_end_addr - hdr->mb.load_addr ) : filesz );
	buffer = phys_to_user ( hdr->mb.load_addr );
	if ( ( rc = prep_segment ( buffer, filesz, memsz ) ) != 0 ) {
	DBGC ( image, "MULTIBOOT %p could not prepare segment: %s\n",
	image, strerror ( rc ) );
	return rc;
	}

	/* Copy image to segment */
	memcpy_user ( buffer, 0, image->data, offset, filesz );

	/* Record execution entry point in image private data field */
	image->priv.phys = hdr->mb.entry_addr;

	return 0;
	}

	/**
	* Load ELF multiboot image into memory
	*
	* @v image Multiboot file
	* @ret rc Return status code
	*/
	static int multiboot_load_elf ( struct image *image ) {
	int rc;

	/* Load ELF image*/
	if ( ( rc = elf_load ( image ) ) != 0 ) {
	DBGC ( image, "MULTIBOOT %p ELF image failed to load: %s\n",
	image, strerror ( rc ) );
	return rc;
	}

	return 0;
	}

	/**
	* Load multiboot image into memory
	*
	* @v image Multiboot file
	* @ret rc Return status code
	*/
	static int multiboot_load ( struct image *image ) {
	struct multiboot_header_info hdr;
	int rc;

	/* Locate multiboot header, if present */
	if ( ( rc = multiboot_find_header ( image, &hdr ) ) != 0 ) {
	DBGC ( image, "MULTIBOOT %p has no multiboot header\n",
	image );
	return rc;
	}
	DBGC ( image, "MULTIBOOT %p found header with flags %08x\n",
	image, hdr.mb.flags );

	/* This is a multiboot image, valid or otherwise */
	if ( ! image->type )
	image->type = &multiboot_image_type;

	/* Abort if we detect flags that we cannot support */
	if ( hdr.mb.flags & MB_UNSUPPORTED_FLAGS ) {
	DBGC ( image, "MULTIBOOT %p flags %08x not supported\n",
	image, ( hdr.mb.flags & MB_UNSUPPORTED_FLAGS ) );
	return -ENOTSUP;
	}

	/* There is technically a bit MB_FLAG_RAW to indicate whether
	* this is an ELF or a raw image. In practice, grub will use
	* the ELF header if present, and Solaris relies on this
	* behaviour.
	*/
	if ( ( ( rc = multiboot_load_elf ( image ) ) != 0 ) &&
	( ( rc = multiboot_load_raw ( image, &hdr ) ) != 0 ) )
	return rc;

	return 0;
	}

	/** Multiboot image type */
	struct image_type multiboot_image_type __image_type ( PROBE_MULTIBOOT ) = {
	.name = "Multiboot",
	.load = multiboot_load,
	.exec = multiboot_exec,
	};