URL
https://opencores.org/ocsvn/openrisc_me/openrisc_me/trunk
Subversion Repositories openrisc_me
[/] [openrisc/] [trunk/] [rtos/] [ecos-2.0/] [packages/] [fs/] [rom/] [v2_0/] [support/] [mk_romfs.c] - Rev 174
Compare with Previous | Blame | View Log
//========================================================================== // // mk_romfs.c // // Create ROM file system image // //========================================================================== //####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Red Hat, Inc. // // eCos 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. // // eCos 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 eCos; if not, write to the Free Software Foundation, Inc., // 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. // // As a special exception, if other files instantiate templates or use macros // or inline functions from this file, or you compile this file and link it // with other works to produce a work based on this file, this file does not // by itself cause the resulting work to be covered by the GNU General Public // License. However the source code for this file must still be made available // in accordance with section (3) of the GNU General Public License. // // This exception does not invalidate any other reasons why a work based on // this file might be covered by the GNU General Public License. // // Alternative licenses for eCos may be arranged by contacting Red Hat, Inc. // at http://sources.redhat.com/ecos/ecos-license/ // ------------------------------------------- //####ECOSGPLCOPYRIGHTEND#### //========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): richard.panton@3glab.com // Contributors: richard.panton@3glab.com // Date: 2000-07-25 // Purpose: ROM file system // Description: This program creates a ROM file system image, suitable // for use with the sample ROM file system implemented by // this package. // * CAUTION! * This is host code and can only be built // in a host, e.g. Linux, environment. // //####DESCRIPTIONEND#### //========================================================================== #include <stdlib.h> #include <string.h> #include <stdio.h> #include <stdarg.h> #include <sys/stat.h> #include <sys/types.h> #include <dirent.h> #include <fcntl.h> #include <unistd.h> #include <errno.h> //========================================================================== // // CONFIGURABLE ITEMS HERE // //========================================================================== // define LONG to be a four byte unsigned integer on the host #define LONG unsigned long // define SHORT to be a two byte unsigned integer on the host #define SHORT unsigned short // All data files should be aligned to this sized boundary (minimum probably 32) #define DATA_ALIGN 32 // The data stored in a directory should be aligned to this size boundary #define DIRECTORY_ALIGN 32 // All executable files should be aligned to this sized boundary (minimum probably 32) #define EXEC_ALIGN 32 // Undefine this if the host filesystem does not support lstat() #define HAS_LSTAT //========================================================================== // Return (n) aligned to the next (b) byte boundary #define ALIGN_TO( n, b ) (( (n) + (b)-1 ) & ~((b)-1)) // Set the stat call to use #ifdef HAS_LSTAT #define get_status( p, b ) lstat( (p), (b) ) #else #define get_status( p, b ) stat( (p), (b) ) #endif // This is how we identify a directory from its mode #define IS_DIRECTORY( m ) (S_ISDIR(m)) // This is how we identify a data file from its mode #define IS_DATAFILE( m ) (S_ISREG(m) && ((m)&S_IXUSR) == 0 ) // This is how we identify an executable from its mode #define IS_EXECUTABLE( m ) (S_ISREG(m) && ((m)&S_IXUSR) != 0 ) // This is how we identify a symbolic link from its mode #define IS_SYMLINK( m ) (S_ISLNK(m)) #define ROMFS_MAGIC 0x526f6d2e //========================================================================= // EXIT CODES #define EXIT_SUCCESS 0 #define EXIT_ARGS 1 #define EXIT_MALLOC 2 #define EXIT_FILESYS 3 #define EXIT_WRITE 4 #define EXIT_SEEK 5 #define EXIT_COMPILE 6 #define EXIT_BUG 7 // These are the structures we will build into the ROMFS image. // The sizes of these structures should be fixed for all architectures typedef struct romfs_dirent { LONG node; // 4 LONG next; // 8 char name[0]; // 8 + strlen(name) + 1 } romfs_dirent; // Aligns to next 32 byte boundary typedef struct romfs_node { LONG mode; // 4 LONG nlink; // 8 SHORT uid; // 10 SHORT gid; // 12 LONG size; // 16 LONG ctime; // 20 LONG data_offset; // 24 char pad[8]; // 32 } romfs_node; // Next node begins here typedef struct romfs_disk { LONG magic; // 4 LONG nodecount; // 8 LONG disksize; // 12 LONG dev_id; // 16 char name[16]; // 32 } romfs_disk; // Nodes start here // This is the holding structure for a node typedef struct node { const char *path; // Filename (inc. path) of a link to this node size_t size; // Size of file/directory/link mode_t st_mode; // Type and permissions uid_t uid; // Owner id gid_t gid; // Group id time_t ctime; // File creation time int nodenum; // Nodenumber of this node in the ROMFS image dev_t device; // Device (for hardlink check) ino_t inode; // Inode (for hardlink check) int nlink; // [DIRECTORIES] Number of sub-directories [FILES] hard links romfs_dirent *entry; // [DIRECTORIES] Points to an array of directory entries int entry_size; // Size to be allocated to file (includes alignment bytes) unsigned long offset; // Offset within ROMFS image of data struct node *sibling; // Points to the next entry in this directory struct node *child; // [DIRECTORIES] Points to any subdirectories struct node *next_in_rom; // Next in ROMFS write order struct node *next_multilink;// Next node that is multilinked } node; static int nodes = 0; static char *prog; static int verbose = 1; static int dowrite = 1; static int bigendian = 0; static int hardlinks = 0; static unsigned long coffset = 0; static node * first = NULL; static node ** last_p = &first; static node * first_multilink = NULL; static node ** last_multilink_p = &first_multilink; static int fd = -1; #define VERB_NONE 0 #define VERB_MINIMUM 1 #define VERB_SUB 2 #define VERB_MAX 3 #define VERB_EXCESSIVE 4 // Use gcc format argument checking on this function, which cannot return static void fatal_error( int exitcode, const char *fmt, ... ) \ __attribute__ (( noreturn,format (printf, 2, 3) )); // Use gcc format argument checking on this function static void verb_printf( int level, const char *fmt, ... ) \ __attribute__ ((format (printf, 2, 3) )); static void fatal_error( int exitcode, const char *fmt, ... ) { va_list v; va_start( v, fmt ); vfprintf( stderr, fmt, v ); exit(exitcode); } static void verb_printf( int level, const char *fmt, ... ){ if ( level <= verbose ) { va_list v; va_start( v,fmt ); vprintf(fmt, v); } } static void *mymalloc( size_t size ) { void *p = malloc(size); if ( !p ) { fatal_error( EXIT_MALLOC, "Out of memory allocating %d bytes\n", size ); } return p; } static void myrealloc( void **o, size_t newsize ) { if ( *o == NULL ) *o = mymalloc( newsize ); else if ( !(*o = realloc( *o, newsize )) ) { fatal_error( EXIT_MALLOC, "Out of memory re-allocating %d bytes\n", newsize ); } } static void outputlong( unsigned char *b, unsigned long w ) { if ( bigendian ) { b[0] = (w>>24) & 0xff; b[1] = (w>>16) & 0xff; b[2] = (w>> 8) & 0xff; b[3] = (w ) & 0xff; } else { b[3] = (w>>24) & 0xff; b[2] = (w>>16) & 0xff; b[1] = (w>> 8) & 0xff; b[0] = (w ) & 0xff; } } static void outputshort( unsigned char *b, unsigned short w ) { if ( bigendian ) { b[0] = (w>> 8) & 0xff; b[1] = (w ) & 0xff; } else { b[1] = (w>> 8) & 0xff; b[0] = (w ) & 0xff; } } static unsigned long ConvertMode( unsigned long posix_mode ) { unsigned long result = 0; if ( S_ISDIR( posix_mode ) ) result |= 1<<0; if ( S_ISCHR( posix_mode ) ) result |= 1<<1; if ( S_ISBLK( posix_mode ) ) result |= 1<<2; if ( S_ISREG( posix_mode ) ) result |= 1<<3; if ( S_ISFIFO(posix_mode ) ) result |= 1<<4; // We cannot create MQ, SEM, or SHM entries here if ( posix_mode & S_IRUSR ) result |= 1<<8; if ( posix_mode & S_IWUSR ) result |= 1<<9; if ( posix_mode & S_IXUSR ) result |= 1<<10; if ( posix_mode & S_IRGRP ) result |= 1<<11; if ( posix_mode & S_IWGRP ) result |= 1<<12; if ( posix_mode & S_IXGRP ) result |= 1<<13; if ( posix_mode & S_IROTH ) result |= 1<<14; if ( posix_mode & S_IWOTH ) result |= 1<<15; if ( posix_mode & S_IXOTH ) result |= 1<<16; if ( posix_mode & S_ISUID ) result |= 1<<17; if ( posix_mode & S_ISGID ) result |= 1<<18; return result; } static const char *AddDirEntry( const char *name, node *parent_node, int node_num ) { int this_size = ((strlen(name) + 4 + 4 + 1) + 31) & ~31; int start = parent_node->size; romfs_dirent *g; myrealloc( (void**)&parent_node->entry, (parent_node->size += this_size) ); g = (romfs_dirent *)((unsigned char *)parent_node->entry + start); memset( (void*)g, '\0', this_size ); outputlong( (char*)&g->node, node_num); outputlong( (char*)&g->next, parent_node->size); strcpy(g->name,name); verb_printf( VERB_MAX, "\t%s --> node %d\n", name, node_num ); return (const char *)g->name; } extern int errno; static node * FindLink( dev_t d, ino_t i ) { // See if the node has been previously included by checking the device/inode // combinations of all known multi-linked nodes node *np = first_multilink; for ( ; np ; np = np->next_multilink ) { if ( np->device == d && np->inode == i ) return np; } return NULL; } static node * GetNodeInfo( const char *path, const char *name, int *hlink ) { char newpath[1024]; node *node, *lnode; struct stat stbuff; sprintf(newpath,"%s/%s",path,name); if ( (get_status(newpath,&stbuff)) < 0 ) { fatal_error(EXIT_FILESYS, "stat(%s) failed: %s\n", newpath, strerror(errno)); } if ( !(stbuff.st_mode & S_IRUSR) ) { fatal_error(EXIT_FILESYS, "\"%s\" is not readable\n", newpath ); } if ( hardlinks && S_ISREG( stbuff.st_mode ) && stbuff.st_nlink > 1 ) { // See if this node has already been loaded lnode = FindLink( stbuff.st_dev, stbuff.st_ino ); if ( lnode ) { lnode->nlink++; *hlink = 1; return lnode; // Return the found link instead } // Create a new node node = mymalloc( sizeof(struct node) ); // Incorporate the new link into the 'multi-linked' node list *last_multilink_p = node; last_multilink_p = &node->next_multilink; } else { // Create a new node node = mymalloc( sizeof(struct node) ); } node->path = strdup( newpath ); // We re-calculate the size for directories node->size = IS_DIRECTORY( stbuff.st_mode ) ? 0 : stbuff.st_size; node->st_mode = stbuff.st_mode; node->uid = stbuff.st_uid; node->gid = stbuff.st_gid; node->ctime = stbuff.st_ctime; node->nodenum = nodes++; node->device = stbuff.st_dev; node->inode = stbuff.st_ino; // We always re-calculate the number of links node->nlink = IS_DIRECTORY( stbuff.st_mode ) ? 2 : 1; node->entry = NULL; node->entry_size = 0; node->offset = 0; node->sibling = NULL; node->child = NULL; node->next_in_rom = NULL; node->next_multilink = NULL; *hlink = 0; return node; } static void ScanDirectory(node *mynode, int p_node) { DIR *dh; struct dirent *e; node **last_p = &mynode->child; node *th; int was_hardlinked; if ( (dh = opendir( mynode->path )) == NULL ) { perror(mynode->path); return; } verb_printf(VERB_EXCESSIVE, "Construct directory '%s'(%d):\n", mynode->path, mynode->nodenum ); // Add . & .. here because they MUST be present in the image AddDirEntry( ".", mynode, mynode->nodenum ); AddDirEntry( "..", mynode, p_node ); while ( (e = readdir( dh )) ) { // Ignore . & .. here because they MAY NOT be in the host filesystem if ( strcmp(e->d_name,".") && strcmp(e->d_name,"..") ) { th = GetNodeInfo( mynode->path, e->d_name, &was_hardlinked ); AddDirEntry( e->d_name, mynode, th->nodenum ); if ( !was_hardlinked ) { verb_printf( VERB_EXCESSIVE, "\t\tNew node %d for entry '%s'\n", th->nodenum, e->d_name); *last_p = th; last_p = &th->sibling; } else { verb_printf( VERB_EXCESSIVE, "\t\tRe-used node %d for entry '%s'\n", th->nodenum, e->d_name); } } } closedir( dh ); verb_printf(VERB_EXCESSIVE,"Completed '%s'. Checking for child directories...\n", mynode->path); for ( th = mynode->child ; th ; th = th->sibling ) { if ( IS_DIRECTORY( th->st_mode ) ) { mynode->nlink++; ScanDirectory( th, mynode->nodenum ); } } } static void AllocateSpaceToDirectories( node *first ) { node *np; for ( np = first ; np ; np = np->sibling ) { if ( IS_DIRECTORY( np->st_mode ) ) { // The first node is a directory. Add its data np->offset = coffset; np->entry_size = ALIGN_TO( np->size, DIRECTORY_ALIGN ); coffset += np->entry_size; verb_printf( VERB_MAX, "\t\tnode %5d : 0x%06lX (+0x%05X)\n", np->nodenum, np->offset, np->entry_size ); // Link this node into the write order chain. // For node 0 (the root), this will overwrite the first pointer with itself *last_p = np; last_p = &np->next_in_rom; } } // Now add any child directories for ( np = first ; np ; np = np->sibling ) { if ( IS_DIRECTORY( np->st_mode ) && np->child ) AllocateSpaceToDirectories( np->child ); } } static void AllocateSpaceToDataFiles( node *first ) { node *np; // There are two loops below. It CAN be done in just one, but this re-orders // the file positions in relation to their inode numbers. To keep it simple // to check, allocation takes place in the first loop, recursion in the second // Search for child data files for ( np = first->child ; np ; np = np->sibling ) { if ( IS_DATAFILE( np->st_mode ) || IS_SYMLINK( np->st_mode ) ) { np->offset = coffset; np->entry_size = ALIGN_TO( np->size, DATA_ALIGN ); coffset += np->entry_size; // Link in to the rom write order list *last_p = np; last_p = &np->next_in_rom; verb_printf( VERB_MAX, "\t\tnode %5d : 0x%06lX (+0x%05X)\n", np->nodenum, np->offset, np->entry_size ); } } // Recurse into sub-directories for ( np = first->child ; np ; np = np->sibling ) { if ( IS_DIRECTORY( np->st_mode ) ) { AllocateSpaceToDataFiles( np ); } } } static void AllocateSpaceToExecutables( node *first ) { node *np; // The first node is a directory. Don't bother with that... // Search for child executables for ( np = first->child ; np ; np = np->sibling ) { if ( IS_EXECUTABLE( np->st_mode ) ) { np->offset = coffset; np->entry_size = ALIGN_TO( np->size, EXEC_ALIGN ); coffset += np->entry_size; // Link in to the rom write order list *last_p = np; last_p = &np->next_in_rom; verb_printf( VERB_MAX, "\t\tnode %5d : 0x%06lX (+0x%05X)\n", np->nodenum, np->offset, np->entry_size ); } } // Recurse into sub-directories for ( np = first->child ; np ; np = np->sibling ) { if ( IS_DIRECTORY( np->st_mode ) ) { AllocateSpaceToExecutables( np ); } } } static void WriteNode( int fd, node *np ) { romfs_node anode; char padhere[9]; outputlong( (char*) &anode.mode, ConvertMode( np->st_mode ) ); outputlong( (char*) &anode.nlink, np->nlink ); outputshort((char*) &anode.uid, np->uid ); outputshort((char*) &anode.gid, np->gid ); outputlong( (char*) &anode.size, np->size ); outputlong( (char*) &anode.ctime, np->ctime ); outputlong( (char*) &anode.data_offset, np->offset ); sprintf( padhere, "<%6d>", np->nodenum ); memcpy( anode.pad, padhere, 8 ); if ( dowrite && write( fd, (void*)&anode, sizeof(anode) ) != sizeof(anode) ) fatal_error(EXIT_WRITE, "Error writing node %d (%s): %s\n", np->nodenum, np->path, strerror(errno) ); } static int WriteNodeAndSiblings( int fd, int nodenum, node *first ) { node *np; for ( np = first ; np ; np = np->sibling ) { if ( np->nodenum != nodenum++ ) { fatal_error(EXIT_BUG, "BUG: Out of sequence node number; got %d, expected %d\n", np->nodenum, nodenum-1); } WriteNode( fd, np ); } for ( np = first ; np ; np = np->sibling ) { if ( IS_DIRECTORY( np->st_mode ) && np->child ) { nodenum = WriteNodeAndSiblings( fd, nodenum, np->child ); } } return nodenum; } static void WriteNodeTable( int fd ) { romfs_disk header; int wnodes; outputlong( (char*) &header.magic, ROMFS_MAGIC ); outputlong( (char*) &header.nodecount, nodes ); outputlong( (char*) &header.disksize, coffset ); outputlong( (char*) &header.dev_id, 0x01020304 ); strcpy( header.name, "ROMFS v1.0" ); if ( dowrite && write( fd, (void*)&header, sizeof(header) ) != sizeof(header) ) fatal_error(EXIT_WRITE, "Error writing ROMFS header: %s\n", strerror(errno) ); if ( (wnodes = WriteNodeAndSiblings( fd, 0, first )) != nodes ) { fatal_error(EXIT_BUG, "BUG: Lost/gained some nodes; wrote %d, expected %d\n", wnodes, nodes ); } } #ifndef O_BINARY #define O_BINARY 0 #endif static void WriteData( int fd, node *np ) { char newpath[1024]; int ffd; unsigned long todo; if ( IS_SYMLINK( np->st_mode ) ) { if ( (ffd = readlink( np->path, newpath, sizeof(newpath) )) < 0 ) fatal_error(EXIT_FILESYS, "Error reading symlink \"%s\": %s\n", np->path, strerror(errno) ); if ( !dowrite ) return; if ( lseek( fd, np->offset, SEEK_SET ) != np->offset ) fatal_error(EXIT_SEEK, "Error seeking to offset 0x%lX: %s\n", np->offset, strerror(errno) ); if ( write( fd, newpath, ffd ) != ffd ) fatal_error(EXIT_WRITE, "Write error: %s\n", strerror(errno) ); return; } if ( (ffd=open(np->path, O_RDONLY | O_BINARY )) < 0 ) fatal_error(EXIT_FILESYS, "Error opening \"%s\": %s\n", np->path, strerror(errno) ); if ( dowrite && lseek( fd, np->offset, SEEK_SET ) != np->offset ) fatal_error(EXIT_SEEK, "Error seeking to offset 0x%lX: %s\n", np->offset, strerror(errno) ); todo = np->size; while ( todo >= 1024 ) { if ( read( ffd, newpath, 1024 ) != 1024 ) fatal_error(EXIT_FILESYS, "Error reading file \"%s\" at offset 0x%lX: %s\n", np->path, np->size - todo, strerror(errno) ); if ( dowrite && write( fd, newpath, 1024 ) != 1024 ) fatal_error(EXIT_WRITE, "Write error: %s\n", strerror(errno) ); todo -= 1024; } if ( todo ) { if ( read( ffd, newpath, todo ) != todo ) fatal_error(EXIT_FILESYS, "Error reading file \"%s\" at offset 0x%lX: %s\n", np->path, np->size - todo, strerror(errno) ); if ( dowrite && write( fd, newpath, todo ) != todo ) fatal_error(EXIT_WRITE, "Write error: %s\n", strerror(errno) ); } close(ffd); } static void WriteDataBlocks( int fd, node *first ) { for ( ; first ; first = first->next_in_rom ) { if ( dowrite && lseek( fd, first->offset, SEEK_SET ) != first->offset ) fatal_error(EXIT_SEEK, "Error seeking to offset 0x%lX: %s\n", first->offset, strerror(errno) ); if ( IS_DIRECTORY( first->st_mode ) ) { if ( dowrite && write( fd, first->entry, first->size ) != first->size ) fatal_error(EXIT_WRITE, "Write error: %s\n", strerror(errno) ); } else { WriteData( fd, first ); } } } static void usage(void) { fprintf(stderr,"\n%s - Create an eCos ROMFS disk image from the files\n",prog); fprintf(stderr,"%*s contained under a specified directory\n\n", strlen(prog), ""); fprintf(stderr,"Usage: %s [options] <fs_root> <fs_file>\n", prog); fprintf(stderr," fs_root is the directory containing the files to package into the ROMFS image\n"); fprintf(stderr," fs_file is the name of the ROMFS image file to create\n"); fprintf(stderr," Options include:\n"); fprintf(stderr," -v / -q increase / decrease verbosity\n"); fprintf(stderr," -n do everything EXCEPT creating the output file\n"); fprintf(stderr," -b write a big-endian image (default is little endian)\n"); fprintf(stderr," -l collapse hard links to a single node\n"); fprintf(stderr,"\n"); exit(EXIT_ARGS); } int main(int ac, char *av[]) { int dummy; prog = av[0]; // Check structure sizes if (sizeof(romfs_node) != 32) { fatal_error(EXIT_COMPILE , "Size of romfs_node is %d, NOT 32\n", sizeof(romfs_node) ); } else if (sizeof(romfs_dirent) != 8) { fatal_error(EXIT_COMPILE , "Size of romfs_dirent is %d, NOT 8\n", sizeof(romfs_dirent) ); } else if (sizeof(romfs_disk) != 32) { fatal_error(EXIT_COMPILE , "Size of romfs_disk is %d, NOT 32\n", sizeof(romfs_disk) ); } // Parse option arguments while ( ac > 1 && av[1][0] == '-' ) { char *o = &av[1][1]; for ( ; *o ; o++ ) { switch ( *o ) { case 'q' : verbose--; break; case 'v' : verbose++; break; case 'n' : dowrite = 0; break; case 'b' : bigendian = 1; break; case 'l' : hardlinks = 1; break; default : fprintf(stderr,"%s: Invalid flag -%c\n", prog, *o ); usage(); } } av++; ac--; } // Check remaining arguments if ( ac != 3 ) usage(); verb_printf( VERB_MINIMUM, "%s: Verbosity %d %s%s endian\n", prog, verbose, dowrite ? "" : "no write, ", bigendian ? "big" : "little" ); // Phase 1. Recursively scan the root directory for files and directories. verb_printf(VERB_MINIMUM, "Phase 1 - Build file list\n"); first = GetNodeInfo( av[1], ".", &dummy ); // Initialize the root node entry. ScanDirectory( first, 0 ); // Phase 2. Work out space allocations for filesystem verb_printf(VERB_MINIMUM, "Phase 2 - Calculate space allocation\n"); coffset = sizeof(romfs_disk) + nodes * sizeof(romfs_node); verb_printf(VERB_MAX,"\t\tnode table : 0x000000 (+0x%05lX) %d nodes\n", coffset, nodes ); // Phase 2a. Work out space allocations for the directories of the filesystem verb_printf(VERB_SUB,"Phase 2a - * Directories\n"); coffset = ALIGN_TO( coffset, DIRECTORY_ALIGN ); AllocateSpaceToDirectories( first ); // Phase 2b. Work out space allocations for the data files of the filesystem verb_printf(VERB_SUB,"Phase 2b - * Regular files\n"); coffset = ALIGN_TO( coffset, DATA_ALIGN ); AllocateSpaceToDataFiles( first ); // Phase 2c. Work out space allocations for the executable files of the filesystem verb_printf(VERB_SUB,"Phase 2c - * Executable files\n"); coffset = ALIGN_TO( coffset, EXEC_ALIGN ); AllocateSpaceToExecutables( first ); // Round off the image size... coffset = ALIGN_TO( coffset, EXEC_ALIGN ); // Phase 3. Write out the image file verb_printf(VERB_MINIMUM, "Phase 3 - Construct ROMFS image file (%ld kb)\n", ALIGN_TO( coffset, 1024 )/1024); if ( dowrite ) { if ( (fd = open( av[2], O_WRONLY|O_CREAT|O_TRUNC|O_BINARY, 0666 )) < 0 ) { fatal_error(EXIT_WRITE,"Failed to open output file '%s', errno=%d\n", av[2], errno ); } } else { verb_printf(VERB_NONE," (No image is being written)\n"); } verb_printf(VERB_SUB,"Phase 3a - * Node table\n"); WriteNodeTable( fd ); verb_printf(VERB_SUB,"Phase 3b - * Data blocks\n"); WriteDataBlocks( fd, first ); if ( fd >= 0 ) close(fd); verb_printf(VERB_MINIMUM, "%s completed\n", av[2] ); return 0; }