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//========================================================================== // // ramfs.c // // RAM file system // //========================================================================== // ####ECOSGPLCOPYRIGHTBEGIN#### // ------------------------------------------- // This file is part of eCos, the Embedded Configurable Operating System. // Copyright (C) 1998, 1999, 2000, 2001, 2002 Free Software Foundation, 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., // 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, 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 v2. // // This exception does not invalidate any other reasons why a work based // on this file might be covered by the GNU General Public License. // ------------------------------------------- // ####ECOSGPLCOPYRIGHTEND#### //========================================================================== //#####DESCRIPTIONBEGIN#### // // Author(s): nickg // Contributors: nickg // Date: 2000-07-25 // Purpose: RAM file system // Description: This is a RAM filesystem for eCos. It attempts to // provide full POSIX-compatible filesystem behaviour // while at the same time being efficient in terms of // time and space used. // // //####DESCRIPTIONEND#### // //========================================================================== // // General Description // =================== // // This is an implementation of a RAM filesystem for eCos. Its goal is // to provide a working example of a filesystem that provides most of // the required POSIX functionality. And obviously it may also be // useful in its own right. // // // Nodes // ----- // // All files and directories are represented by node objects. Each // ramfs_node structure contains the following fields: // // mode - Node type, file or directory. // refcnt - Number of references to this node. For files each open counts as // a reference and for directories a node is referenced when it is made // current directory, or is opened for reading. // nlink - Number of links to this node. Each directory entry that references // this node is a link. // size - Size of the data in this node in bytes. // atime - Last time this node was accessed. // mtime - Last time the data in this node was modified. // ctime - Last time the status information in this node was changed. // // The data storage in a node is controlled by the configuration and // can take two forms. These will be described later. // // Directories // ----------- // // A directory is a node whose data is a list of directory entries. To // simplify management of these, long directory entries are split into // a chain of fixed size ramfs_dirent structures. These contain the // following fields: // // node - Pointer to node referenced by this entry. This is present in // every directory entry fragment // inuse - Set to 1 if this entry is in use, zero if it is free. // first - Set to 1 if this is the first fragment of a directory entry. // last - Set to 1 if this is the last fragment of a directory entry. // namelen - The size of the whole file name. // fraglen - The number of bytes of the file name that are stored in this // fragment. // next - The offset of the next fragment of this directory entry. // name - The characters of the fragment of the file name stored in this // entry. // // Small file names are stored in a single fragment. Longer names are // stored in a chain of fragments. // // Data Storage // ------------ // // Two data storage mechanisms may be configured, the SIMPLE and the // BLOCKS mechanisms. // // SIMPLE Data Storage // ~~~~~~~~~~~~~~~~~~~ // // This mechanism simply uses malloc() and free() to allocate the // memory for both nodes and file data. File data is stored in a // single malloced vector that is realloced as necessary to acquire // more space. // // The advantage of this approach is that the RAM filesystem only uses // as much memory as it needs, the rest is available for use by other // components. It also requires much simpler data structures and code // in the filesystem to manage. However, if any files get to be a // significant proportion of the size of the heap, there is the danger // that fragmentation will prevent any further extension of some // files, even if there is enough memory in total. It also requires an // implementation of malloc() to be present. If this needs to be // present for other components,then this is not a significant // overhead, but including it just for use by this filesystem // represents a major addition of code and data structures. // // // BLOCKS Data Storage // ~~~~~~~~~~~~~~~~~~~ // // This mechanism divides the memory used for file storage into fixed // sized blocks. These blocks may either be allocated using // malloc()/free(), or may be obtained from a array of blocks reserved // for the purpose. Configuration allows the block size to be // selected, as well as the allocation mechanism, and in the case of a // block array, whether it is defined here or by an external // component. // // Data storage in nodes is arranges in three arrays of pointers to // blocks. The first array points directly to data blocks, the second // to blocks which themselves contain pointers to data blocks, and the // third to blocks which contain pointers to blocks which contain // pointers to data blocks. In the default configuration These last // two arrays have only one element each. // // The following shows how the data is arranged in a fully populated // file with a 256 byte block size using the default configuration. // // Node // ~ ~ // | | // | | // +------------+ // | *------+--------> data block 0 // +------------+ // | *------+--------> data block 1 // +------------+ // | *------+--------> data block 2 // +------------+ // | *------+--------> data block 3 // +------------+ // | *------+--------> data block 4 // +------------+ // | *------+--------> data block 5 // +------------+ // | *------+--------> data block 6 // +------------+ // | *------+--------> data block 7 // +------------+ // | *------+--------> +------------+ // +------------+ | *------+--------> data block 8 // | *------+----+ +------------+ // +------------+ | | | // | ~ ~ // | | | // | +------------+ // | | *------+--------> data block 71 // | +------------+ // | // +---->+------------+ +------------+ // | *------+-------->| *------+---->data block 72 // +------------+ +------------+ // | | | | // ~ ~ ~ ~ // | | | | // +------------+ +------------+ // | *------+---+ | *------+----> data block 135 // +------------+ | +------------+ // | // | +------------+ // +---->| *------+----> data block 4104 // +------------+ // | | // ~ ~ // | | // +------------+ // | *------+----> data block 4167 // +------------+ // // // // The advantages of this approach are that, first, memory usage is // divided into discreet fixed size blocks which are easier to // manage. When using malloc() to allocate them, they will fit into // any free memory of at least the right size. Using the block array // option removes the need to have a malloc() implementation at all. // // The disadvantages of this mechanism are that, first, when using // malloc() to allocate blocks, the per-block memory allocator // overhead is paid for each block, rather than per file. This may // result in less memory overall being available for data // storage. When using the block array, it is permanently reserved for // use by the ram filesystem, and is not available for use by other // components. // //========================================================================== #include <pkgconf/system.h> #include <pkgconf/hal.h> #include <pkgconf/kernel.h> #include <pkgconf/io_fileio.h> #include <pkgconf/fs_ram.h> #include <cyg/kernel/ktypes.h> // base kernel types #include <cyg/infra/cyg_trac.h> // tracing macros #include <cyg/infra/cyg_ass.h> // assertion macros #include <unistd.h> #include <sys/types.h> #include <fcntl.h> #include <sys/stat.h> #include <errno.h> #include <dirent.h> #include <stdlib.h> #include <string.h> #include <cyg/fileio/fileio.h> #include <cyg/kernel/kapi.h> #include <cyg/infra/diag.h> //========================================================================== // Sizes derived from configuration // ------------------------------------------------------------------------- // Simple malloc based allocator parameters #ifdef CYGPKG_FS_RAM_SIMPLE #define RAMFS_FILESIZE_MAX UINT_MAX #else // ------------------------------------------------------------------------- // Block allocator parameters // The number of nodes per block #define RAMFS_NODES_PER_BLOCK (CYGNUM_RAMFS_BLOCK_SIZE/sizeof(ramfs_node)) // The number of indirect pointers that can be stored in a single data block #define RAMFS_INDIRECT_PER_BLOCK (CYGNUM_RAMFS_BLOCK_SIZE/sizeof(ramfs_block *)) // The number of directory entries that can be stored in a single data block #define RAMFS_DIRENT_PER_BLOCK (CYGNUM_RAMFS_BLOCK_SIZE/sizeof(ramfs_dirent)) // Number of bytes contained in a one level indirect block #define RAMFS_INDIRECT1_BLOCK_EXTENT (RAMFS_INDIRECT_PER_BLOCK* \ CYGNUM_RAMFS_BLOCK_SIZE) // number of bytes contained in a two level indirect block #define RAMFS_INDIRECT2_BLOCK_EXTENT (RAMFS_INDIRECT_PER_BLOCK* \ RAMFS_INDIRECT_PER_BLOCK* \ CYGNUM_RAMFS_BLOCK_SIZE) // The maximum data offset for data directly accessed from the node #define RAMFS_DIRECT_MAX (CYGNUM_RAMFS_BLOCKS_DIRECT*CYGNUM_RAMFS_BLOCK_SIZE) // The maximum data offset for data accessed from the single level indirect blocks #define RAMFS_INDIRECT1_MAX (RAMFS_DIRECT_MAX+ \ (CYGNUM_RAMFS_BLOCKS_INDIRECT1* \ RAMFS_INDIRECT1_BLOCK_EXTENT)) // The maximum data offset for data accessed from the two level indirect blocks #define RAMFS_INDIRECT2_MAX (RAMFS_INDIRECT1_MAX+ \ (CYGNUM_RAMFS_BLOCKS_INDIRECT2* \ RAMFS_INDIRECT2_BLOCK_EXTENT)) // The maximum size of a file #define RAMFS_FILESIZE_MAX RAMFS_INDIRECT2_MAX #endif //========================================================================== // Forward definitions // Filesystem operations static int ramfs_mount ( cyg_fstab_entry *fste, cyg_mtab_entry *mte ); static int ramfs_umount ( cyg_mtab_entry *mte ); static int ramfs_open ( cyg_mtab_entry *mte, cyg_dir dir, const char *name, int mode, cyg_file *fte ); static int ramfs_unlink ( cyg_mtab_entry *mte, cyg_dir dir, const char *name ); static int ramfs_mkdir ( cyg_mtab_entry *mte, cyg_dir dir, const char *name ); static int ramfs_rmdir ( cyg_mtab_entry *mte, cyg_dir dir, const char *name ); static int ramfs_rename ( cyg_mtab_entry *mte, cyg_dir dir1, const char *name1, cyg_dir dir2, const char *name2 ); static int ramfs_link ( cyg_mtab_entry *mte, cyg_dir dir1, const char *name1, cyg_dir dir2, const char *name2, int type ); static int ramfs_opendir ( cyg_mtab_entry *mte, cyg_dir dir, const char *name, cyg_file *fte ); static int ramfs_chdir ( cyg_mtab_entry *mte, cyg_dir dir, const char *name, cyg_dir *dir_out ); static int ramfs_stat ( cyg_mtab_entry *mte, cyg_dir dir, const char *name, struct stat *buf); static int ramfs_getinfo ( cyg_mtab_entry *mte, cyg_dir dir, const char *name, int key, void *buf, int len ); static int ramfs_setinfo ( cyg_mtab_entry *mte, cyg_dir dir, const char *name, int key, void *buf, int len ); // File operations static int ramfs_fo_read (struct CYG_FILE_TAG *fp, struct CYG_UIO_TAG *uio); static int ramfs_fo_write (struct CYG_FILE_TAG *fp, struct CYG_UIO_TAG *uio); static int ramfs_fo_lseek (struct CYG_FILE_TAG *fp, off_t *pos, int whence ); static int ramfs_fo_ioctl (struct CYG_FILE_TAG *fp, CYG_ADDRWORD com, CYG_ADDRWORD data); static int ramfs_fo_fsync (struct CYG_FILE_TAG *fp, int mode ); static int ramfs_fo_close (struct CYG_FILE_TAG *fp); static int ramfs_fo_fstat (struct CYG_FILE_TAG *fp, struct stat *buf ); static int ramfs_fo_getinfo (struct CYG_FILE_TAG *fp, int key, void *buf, int len ); static int ramfs_fo_setinfo (struct CYG_FILE_TAG *fp, int key, void *buf, int len ); // Directory operations static int ramfs_fo_dirread (struct CYG_FILE_TAG *fp, struct CYG_UIO_TAG *uio); static int ramfs_fo_dirlseek (struct CYG_FILE_TAG *fp, off_t *pos, int whence ); //========================================================================== // Filesystem table entries // ------------------------------------------------------------------------- // Fstab entry. // This defines the entry in the filesystem table. // For simplicity we use _FILESYSTEM synchronization for all accesses since // we should never block in any filesystem operations. FSTAB_ENTRY( ramfs_fste, "ramfs", 0, CYG_SYNCMODE_FILE_FILESYSTEM|CYG_SYNCMODE_IO_FILESYSTEM, ramfs_mount, ramfs_umount, ramfs_open, ramfs_unlink, ramfs_mkdir, ramfs_rmdir, ramfs_rename, ramfs_link, ramfs_opendir, ramfs_chdir, ramfs_stat, ramfs_getinfo, ramfs_setinfo); // ------------------------------------------------------------------------- // File operations. // This set of file operations are used for normal open files. static cyg_fileops ramfs_fileops = { ramfs_fo_read, ramfs_fo_write, ramfs_fo_lseek, ramfs_fo_ioctl, cyg_fileio_seltrue, ramfs_fo_fsync, ramfs_fo_close, ramfs_fo_fstat, ramfs_fo_getinfo, ramfs_fo_setinfo }; // ------------------------------------------------------------------------- // Directory file operations. // This set of operations are used for open directories. Most entries // point to error-returning stub functions. Only the read, lseek and // close entries are functional. static cyg_fileops ramfs_dirops = { ramfs_fo_dirread, (cyg_fileop_write *)cyg_fileio_enosys, ramfs_fo_dirlseek, (cyg_fileop_ioctl *)cyg_fileio_enosys, cyg_fileio_seltrue, (cyg_fileop_fsync *)cyg_fileio_enosys, ramfs_fo_close, (cyg_fileop_fstat *)cyg_fileio_enosys, (cyg_fileop_getinfo *)cyg_fileio_enosys, (cyg_fileop_setinfo *)cyg_fileio_enosys }; //========================================================================== // Data typedefs // Some forward typedefs for the main data structures. struct ramfs_node; typedef struct ramfs_node ramfs_node; struct ramfs_dirent; typedef struct ramfs_dirent ramfs_dirent; #ifndef CYGPKG_FS_RAM_SIMPLE typedef cyg_uint8 ramfs_block[CYGNUM_RAMFS_BLOCK_SIZE]; #endif //========================================================================== // File and directory node // This data structure represents a file or directory. struct ramfs_node { mode_t mode; // node type cyg_ucount32 refcnt; // open file/current dir references nlink_t nlink; // number of links to this node size_t size; // size of file in bytes time_t atime; // last access time time_t mtime; // last modified time time_t ctime; // last changed status time #ifdef CYGPKG_FS_RAM_SIMPLE // The data storage in this case consists of a single // malloced memory block, together with its size. size_t datasize; // size of data block cyg_uint8 *data; // malloced data buffer #else // The data storage in this case consists of arrays of pointers // to data blocks. #if CYGNUM_RAMFS_BLOCKS_DIRECT > 0 // Directly accessible blocks from the inode. ramfs_block *direct[CYGNUM_RAMFS_BLOCKS_DIRECT]; #endif #if CYGNUM_RAMFS_BLOCKS_INDIRECT1 > 0 // Single level indirection ramfs_block **indirect1[CYGNUM_RAMFS_BLOCKS_INDIRECT1]; #endif #if CYGNUM_RAMFS_BLOCKS_INDIRECT2 > 0 // Two level indirection ramfs_block ***indirect2[CYGNUM_RAMFS_BLOCKS_INDIRECT2]; #endif #endif }; //========================================================================== // Directory entry. // Fixed sized entry containing a fragment of the name of a file/directory. struct ramfs_dirent { ramfs_node *node; // pointer to node unsigned int inuse:1, // entry in use? first:1, // first directory entry fragment? last:1, // last directory entry fragment? namelen:8, // bytes in whole name fraglen:8; // bytes in name fragment off_t next; // offset of next dirent // Name fragment, fills rest of entry. char name[CYGNUM_RAMFS_DIRENT_SIZE- sizeof(ramfs_node *)- sizeof( cyg_uint32)- sizeof(off_t)]; }; //========================================================================== // Directory search data // Parameters for a directory search. The fields of this structure are // updated as we follow a pathname through the directory tree. struct ramfs_dirsearch { ramfs_node *dir; // directory to search const char *path; // path to follow ramfs_node *node; // Node found const char *name; // last name fragment used int namelen; // name fragment length cyg_bool last; // last name in path? }; typedef struct ramfs_dirsearch ramfs_dirsearch; //========================================================================== // Forward defs static int del_direntry( ramfs_node *dir, const char *name, int namelen ); //========================================================================== // Block array // This is used for block allocation when malloc is not being used. #ifdef CYGPKG_FS_RAM_BLOCKS_ARRAY # ifdef CYGPKG_FS_RAM_BLOCKS_ARRAY_EXTERN // Array is defined externally with a user-supplied name __externC ramfs_block CYGPKG_FS_RAM_BLOCKS_ARRAY_NAME[CYGNUM_FS_RAM_BLOCKS_ARRAY_SIZE]; // Translate into a usable common name #define ramfs_block_array CYGPKG_FS_RAM_BLOCKS_ARRAY_NAME # else // Array is defined here static ramfs_block cyg_ramfs_block_array[CYGNUM_FS_RAM_BLOCKS_ARRAY_SIZE]; #define ramfs_block_array cyg_ramfs_block_array # endif // Pointer to list of free blocks static ramfs_block *block_free_list = NULL; #endif //========================================================================== // Block allocation #ifndef CYGPKG_FS_RAM_SIMPLE // ------------------------------------------------------------------------- // block_init() // Initialize the block allocator by chaining them all together on // block_free_list. #ifdef CYGPKG_FS_RAM_BLOCKS_ARRAY static void block_init(void) { static cyg_bool initialized = false; int i; if( !initialized ) { for( i = 0; i < CYGNUM_FS_RAM_BLOCKS_ARRAY_SIZE; i++ ) { ramfs_block *b = &ramfs_block_array[i]; *(ramfs_block **)b = block_free_list; block_free_list = b; } initialized = true; } } #endif // ------------------------------------------------------------------------- // block_alloc() // Allocate a block for data storage. // If we have a block array, just pick the first off the free list. // If we are mallocing, call malloc() to get it. static ramfs_block *block_alloc(void) { ramfs_block *b; #ifdef CYGPKG_FS_RAM_BLOCKS_ARRAY block_init(); // Check blocks are initialized // pick first block off free list. b = block_free_list; // and advance list if( b != NULL ) block_free_list = *(ramfs_block **)b; #else b = malloc(CYGNUM_RAMFS_BLOCK_SIZE); #endif // Clear the block to zero if it was allocated if( b != NULL ) memset( b, 0, CYGNUM_RAMFS_BLOCK_SIZE ); return b; } // ------------------------------------------------------------------------- // block_free() // Free a block. Depending on the configuration send it back to the // heap or put it back on free list. static void block_free( ramfs_block *b ) { #ifdef CYGPKG_FS_RAM_BLOCKS_ARRAY // Put the block back on the free list *(ramfs_block **)b = block_free_list; block_free_list = b; #else // Call free() to return it to the memory pool free( b ); #endif } #endif //========================================================================== // Node buffer management // There are two versions of this, one for the _SIMPLE variant and one for // the _BLOCKS variant. In both cases the interface to this code is via the // findbuffer_node() and freebuffer_node() functions. #ifdef CYGPKG_FS_RAM_SIMPLE //========================================================================== // SIMPLE buffer management. // Each node has a data buffer pointer and a size. This buffer is // realloc()ed as needed. // ------------------------------------------------------------------------- // findbuffer_node() // return a pointer to the data at the indicated file position, extending // the buffer if required. static int findbuffer_node( ramfs_node *node, // node pointer off_t pos, // data position to get cyg_uint8 **buffer, // returned buffer pointer size_t *size, // returned buffer size cyg_bool alloc) // extend allocation? { if( alloc && (pos >= node->datasize || node->datasize == 0) ) { // If we are allowed to alloc new data, and we are at the end of the // current data allocation, or there is no data present, allocate or // extend the data buffer. cyg_uint8 *newdata; if( node->data == NULL ) newdata = malloc( CYGNUM_RAMFS_REALLOC_INCREMENT ); else newdata = realloc( node->data, pos+CYGNUM_RAMFS_REALLOC_INCREMENT ); if( newdata == NULL ) return ENOSPC; else memset( newdata + node->datasize, 0, pos + CYGNUM_RAMFS_REALLOC_INCREMENT - node->datasize ); node->data = newdata; node->datasize = pos+CYGNUM_RAMFS_REALLOC_INCREMENT; } else if( pos > node->datasize ) { // Indicate end of data. *size = 0; return ENOERR; } *buffer = node->data+pos; *size = node->datasize-pos; return ENOERR; } // ------------------------------------------------------------------------- // freebuffer_node() // Empty out the data storage from the node. static int freebuffer_node( ramfs_node *node ) { if( node->data != NULL ) { free( node->data ); } node->data = NULL; node->datasize = 0; return ENOERR; } //========================================================================== #else //========================================================================== // _BLOCKS storage management. // Data storage in the node is by means of a set of arrays of pointers to // blocks. The first array points directly to the data blocks. Subsequent // arrays point to single and double indirect blocks respectively. // ------------------------------------------------------------------------- // findbuffer_direct() // Indexes into an array of block pointers and extracts a pointer to the // data at offset _pos_, allocating new blocks if required. static int findbuffer_direct( off_t pos, ramfs_block **blocks, int nblocks, cyg_uint8 **buffer, size_t *size, cyg_bool alloc) { int bi = pos / CYGNUM_RAMFS_BLOCK_SIZE; int bpos = pos % CYGNUM_RAMFS_BLOCK_SIZE; ramfs_block *b; *buffer = NULL; *size = CYGNUM_RAMFS_BLOCK_SIZE - bpos; if( bi >= nblocks ) return ENOERR; b = blocks[bi]; if( b == NULL ) { // There is no block there. If _alloc_ is true we can fill the // slot in with a new block. If it is false, we indicate there // is no block and size indicates where the block would end if // it existed. if( alloc ) { b = block_alloc(); if( b == NULL ) return ENOSPC; blocks[bi] = b; } else return ENOERR; } *buffer = &((*b)[bpos]); return ENOERR; } // ------------------------------------------------------------------------- // findbuffer_indirect1() // Indexes into an array of pointers to blocks containing pointers to // blocks and extracts a pointer to the data at offset _pos_, // allocating new blocks if required. #if CYGNUM_RAMFS_BLOCKS_INDIRECT1 > 0 static int findbuffer_indirect1( off_t pos, ramfs_block ***blocks, int nblocks, cyg_uint8 **buffer, size_t *size, cyg_bool alloc) { int bi = pos / RAMFS_INDIRECT1_BLOCK_EXTENT; int bpos = pos % RAMFS_INDIRECT1_BLOCK_EXTENT; int err; cyg_uint8 *b; size_t sz; // Use findbuffer_direct() to index and allocate // the first level indirect block. err = findbuffer_direct( bi*CYGNUM_RAMFS_BLOCK_SIZE, (ramfs_block **)blocks, nblocks, &b, &sz, alloc); if( err != ENOERR ) return err; if( sz == 0 ) { *size = 0; return ENOERR; } // Use findbuffer_direct() on the first level indirect // block to allocate and return the data pointer. return findbuffer_direct( bpos, blocks[bi], RAMFS_INDIRECT_PER_BLOCK, buffer, size, alloc); } #endif // ------------------------------------------------------------------------- // findbuffer_indirect1() // Indexes into an array of pointers to blocks containing pointers to // blocks containing pointers to blocks (!) and extracts a pointer to // the data at offset _pos_, allocating new blocks if required. #if CYGNUM_RAMFS_BLOCKS_INDIRECT2 > 0 static int findbuffer_indirect2( off_t pos, ramfs_block ****blocks, int nblocks, cyg_uint8 **buffer, size_t *size, cyg_bool alloc) { int bi = pos / RAMFS_INDIRECT2_BLOCK_EXTENT; int bpos = pos % RAMFS_INDIRECT2_BLOCK_EXTENT; int err; cyg_uint8 *b; size_t sz; // Use findbuffer_direct() to index and allocate // the first level indirect block. err = findbuffer_direct( bi*CYGNUM_RAMFS_BLOCK_SIZE, (ramfs_block **)blocks, nblocks, &b, &sz, alloc); if( err != ENOERR ) return err; if( sz == 0 ) { *size = 0; return ENOERR; } // Use findbuffer_indirect1() on the first level indirect block to // index and allocate the next level indirect block and the data // block. return findbuffer_indirect1( bpos, blocks[bi], RAMFS_INDIRECT_PER_BLOCK, buffer, size, alloc); } #endif // ------------------------------------------------------------------------- // findbuffer_node() // Depending on the offset and configuration, call the appropriate // function to get the buffer pointer. static int findbuffer_node( ramfs_node *node, off_t pos, cyg_uint8 **buffer, size_t *size, cyg_bool alloc) { #if CYGNUM_RAMFS_BLOCKS_DIRECT > 0 if( pos < RAMFS_DIRECT_MAX ) return findbuffer_direct( pos, node->direct, CYGNUM_RAMFS_BLOCKS_DIRECT, buffer, size, alloc); #endif #if CYGNUM_RAMFS_BLOCKS_INDIRECT1 > 0 if( pos < RAMFS_INDIRECT1_MAX ) return findbuffer_indirect1( pos - RAMFS_DIRECT_MAX, node->indirect1, CYGNUM_RAMFS_BLOCKS_INDIRECT1, buffer, size, alloc); #endif #if CYGNUM_RAMFS_BLOCKS_INDIRECT2 > 0 if( pos < RAMFS_INDIRECT2_MAX ) return findbuffer_indirect2( pos - RAMFS_INDIRECT1_MAX, node->indirect2, CYGNUM_RAMFS_BLOCKS_INDIRECT2, buffer, size, alloc); #endif return ENOSPC; } // ------------------------------------------------------------------------- // freeblock_list() // Free a list of data blocks. static void freeblock_list( ramfs_block *blocks[],int nblocks ) { int i; for( i = 0; i < nblocks ; i++ ) { if( blocks[i] != NULL ) { block_free( blocks[i] ); blocks[i] = NULL; } } } // ------------------------------------------------------------------------- // freebuffer_node() // Free all the data blocks in the node and clear the pointers. static int freebuffer_node( ramfs_node *node ) { #if CYGNUM_RAMFS_BLOCKS_DIRECT > 0 freeblock_list( node->direct, CYGNUM_RAMFS_BLOCKS_DIRECT ); #endif #if CYGNUM_RAMFS_BLOCKS_INDIRECT1 > 0 { int i; for( i = 0; i < CYGNUM_RAMFS_BLOCKS_INDIRECT1 ; i++ ) { if( node->indirect1[i] != NULL ) { freeblock_list( (ramfs_block **)node->indirect1[i], RAMFS_INDIRECT_PER_BLOCK ); block_free( (ramfs_block *)node->indirect1[i] ); node->indirect1[i] = NULL; } } } #endif #if CYGNUM_RAMFS_BLOCKS_INDIRECT2 > 0 { int i; for( i = 0; i < CYGNUM_RAMFS_BLOCKS_INDIRECT2 ; i++ ) { if( node->indirect2[i] != NULL ) { ramfs_block ***b = node->indirect2[i]; int j; for( j = 0; j < RAMFS_INDIRECT_PER_BLOCK ; j++ ) { if( b[j] != NULL ) { freeblock_list( (ramfs_block **)b[j], RAMFS_INDIRECT_PER_BLOCK ); block_free( (ramfs_block *)b[j] ); b[j] = NULL; } } block_free( (ramfs_block *)node->indirect2[i] ); node->indirect2[i] = NULL; } } } #endif return ENOERR; } //========================================================================== #endif //========================================================================== // Node allocation // ------------------------------------------------------------------------- // alloc_node() // Allocate a node and initialize it. // For the _SIMPLE allocation option, we just malloc it. For the // _BLOCKS option we allocate a block and use that. In theory we could // pack several nodes into a single block, but we don't at present due // to sheer lazyness. static ramfs_node *alloc_node( mode_t mode ) { #ifdef CYGPKG_FS_RAM_SIMPLE ramfs_node *node = malloc( sizeof( ramfs_node ) ); if( node == NULL ) return NULL; #else ramfs_block *b = block_alloc(); ramfs_node *node; if( b == NULL ) return NULL; node = (ramfs_node *)b; #endif memset( node, 0, sizeof(ramfs_node) ); node->mode = mode; node->refcnt = 0; node->nlink = 0; node->size = 0; node->atime = node->mtime = node->ctime = cyg_timestamp(); #ifdef CYGPKG_FS_RAM_SIMPLE node->datasize = 0; node->data = NULL; #else // The node is already all zero #endif return node; } // ------------------------------------------------------------------------- // free_node() // Release a node either back to the free pool or back into the block // pool. static void free_node( ramfs_node *node ) { #ifdef CYGPKG_FS_RAM_SIMPLE free( node ); #else block_free( (ramfs_block *)node ); #endif } //========================================================================== // Ref count and nlink management // ------------------------------------------------------------------------- // dec_refcnt() // Decrment the reference count on a node. If this makes the ref count // zero, and the number of links is either zero for a file or one for // a node, then this node is detached from the directory tree and can // be freed. static int dec_refcnt( ramfs_node *node ) { int err = ENOERR; node->refcnt--; if( node->refcnt == 0 && ((S_ISREG(node->mode) && node->nlink == 0 ) || (S_ISDIR(node->mode) && node->nlink == 1) ) ) { // This node it now totally detached from the directory tree, // so delete it. if( S_ISDIR(node->mode) ) { del_direntry( node, ".", 1 ); del_direntry( node, "..", 2 ); } err = freebuffer_node( node ); if( err == ENOERR ) free_node( node ); } return err; } // ------------------------------------------------------------------------- // dec_nlink() // Decrement a node's link count. Since this has to do all the same // work as dec_refcnt() we implement this using that function by // essentially transferring the count to refcnt and then decrement // that. static int dec_nlink( ramfs_node *node ) { node->refcnt++; node->nlink--; return dec_refcnt( node ); } //========================================================================== // Directory operations // ------------------------------------------------------------------------- // add_direntry() // Add an entry to a directory. This is added as a chain of entry // fragments until the name is exhausted. static int add_direntry( ramfs_node *dir, // dir to add to const char *name, // name to add int namelen, // length of name ramfs_node *node // node to reference ) { off_t pos = 0; #ifdef CYGPKG_FS_RAM_SIMPLE off_t prev_pos = 0; #endif ramfs_dirent *d = NULL, *dp = NULL; cyg_bool isfirst = true; // Loop inserting fragments of the name into the directory until we // have found a home for them all. while( namelen > 0 ) { int fraglen = namelen; if( fraglen > sizeof(d->name) ) fraglen = sizeof(d->name); // Find a free fragment for(;;) { cyg_uint8 *buf; size_t size; int err = findbuffer_node( dir, pos, &buf, &size, true ); if( err != ENOERR ) return err; d = (ramfs_dirent *)buf; if( size < sizeof(ramfs_dirent) || d->inuse ) { pos += sizeof(ramfs_dirent); continue; } break; } #ifdef CYGPKG_FS_RAM_SIMPLE // Tricky! Here we have to look up the previous segment as // reallocating could have moved it. if( !isfirst ) { cyg_uint8 *buf; size_t size; int err; err = findbuffer_node( dir, prev_pos, &buf, &size, false ); if( err != ENOERR ) return err; dp = (ramfs_dirent *) buf; } #endif // d now points to a free dirent structure d->node = node; d->inuse = 1; d->first = isfirst; d->namelen = namelen; d->fraglen = fraglen; if( dp ) dp->next = pos; memcpy( d->name, name, fraglen ); name += fraglen; namelen -= fraglen; #ifdef CYGPKG_FS_RAM_SIMPLE prev_pos = pos; #endif pos += sizeof(ramfs_dirent); dp = d; isfirst = false; } d->last = 1; // Mark last fragment // Update directory times dir->mtime = dir->ctime = cyg_timestamp(); // Extend dir size if necessary if( pos > dir->size ) dir->size = pos; // Count the new link node->nlink++; return ENOERR; } // ------------------------------------------------------------------------- // find_direntry() // Find a directory entry for the name and return a pointer to the first // entry fragment. static ramfs_dirent *find_direntry( ramfs_node *dir, const char *name, int namelen ) { ramfs_dirent *first = NULL; off_t pos = 0; int err; // Loop over all the entries until a match is found or we run out // of data. while( pos < dir->size ) { const char *frag = name; ramfs_dirent *d; cyg_uint8 *buf; size_t size; // look for a first name fragment for(;;) { err = findbuffer_node( dir, pos, &buf, &size, false ); if( err != ENOERR || size == 0) return NULL; d = (ramfs_dirent *)buf; if( size < sizeof(ramfs_dirent) || !d->inuse || !d->first ) { pos += sizeof(ramfs_dirent); if ( pos < dir->size ) continue; // End if directory, didn't find it. return NULL; } break; } // Here we have got a first fragment of a name, check it // against the name we are looking for. First check that they // are the same length. if( d->namelen == namelen ) { // We have a potential candidate here... first = d; // Save it for later // Now check that all the name fragments match for(;;) { int fraglen = namelen-(frag-name); if( fraglen > d->fraglen ) fraglen = d->fraglen; // compare strings, if different, look for another if( memcmp( frag, d->name, fraglen ) != 0 ) { break; } frag += fraglen; // If we are at the last fragment, then the whole name string // has matched and we have a successful search. if( d->last ) return first; // Otherwise move on to next entry in chain err = findbuffer_node( dir, d->next, &buf, &size, false ); if( err != ENOERR ) return NULL; d = (ramfs_dirent *)buf; } } pos += sizeof(ramfs_dirent); } return NULL; } // ------------------------------------------------------------------------- // del_direntry() // Delete a named directory entry. Find it and then follow the chain // deleting the fragments as we go. static int del_direntry( ramfs_node *dir, const char *name, int namelen ) { ramfs_dirent *d = find_direntry( dir, name, namelen ); if( d == NULL ) return ENOENT; for(;;) { int err; cyg_uint8 *buf; size_t size; d->inuse = 0; if( d->last ) break; err = findbuffer_node( dir, d->next, &buf, &size, false ); if( err != ENOERR ) return ENOENT; d = (ramfs_dirent *)buf; } dec_nlink( d->node ); return ENOERR; } //========================================================================== // Directory search // ------------------------------------------------------------------------- // init_dirsearch() // Initialize a dirsearch object to start a search static void init_dirsearch( ramfs_dirsearch *ds, ramfs_node *dir, const char *name) { ds->dir = dir; ds->path = name; ds->node = dir; ds->name = name; ds->namelen = 0; ds->last = false; } // ------------------------------------------------------------------------- // find_entry() // Search a single directory for the next name in a path and update the // dirsearch object appropriately. static int find_entry( ramfs_dirsearch *ds ) { ramfs_node *dir = ds->dir; const char *name = ds->path; const char *n = name; int namelen = 0; ramfs_dirent *d; // check that we really have a directory if( !S_ISDIR(dir->mode) ) return ENOTDIR; // Isolate the next element of the path name. while( *n != '\0' && *n != '/' ) n++, namelen++; // Check if this is the last path element. while( *n == '/') n++; if( *n == '\0' ) ds->last = true; // update name in dirsearch object ds->name = name; ds->namelen = namelen; // Here we have the name and its length set up. // Search the directory for a matching entry d = find_direntry( dir, name, namelen ); if( d == NULL ) return ENOENT; // pass back the node we have found ds->node = d->node; return ENOERR; } // ------------------------------------------------------------------------- // ramfs_find() // Main interface to directory search code. This is used in all file // level operations to locate the object named by the pathname. static int ramfs_find( ramfs_dirsearch *d ) { int err; // Short circuit empty paths if( *(d->path) == '\0' ) return ENOERR; // iterate down directory tree until we find the object // we want. for(;;) { err = find_entry( d ); if( err != ENOERR ) return err; if( d->last ) return ENOERR; // Update dirsearch object to search next directory. d->dir = d->node; d->path += d->namelen; while( *(d->path) == '/' ) d->path++; // skip dirname separators } } //========================================================================== // Pathconf support // This function provides support for pathconf() and fpathconf(). static int ramfs_pathconf( ramfs_node *node, struct cyg_pathconf_info *info ) { int err = ENOERR; switch( info->name ) { case _PC_LINK_MAX: info->value = LINK_MAX; break; case _PC_MAX_CANON: info->value = -1; // not supported err = EINVAL; break; case _PC_MAX_INPUT: info->value = -1; // not supported err = EINVAL; break; case _PC_NAME_MAX: info->value = NAME_MAX; break; case _PC_PATH_MAX: info->value = PATH_MAX; break; case _PC_PIPE_BUF: info->value = -1; // not supported err = EINVAL; break; case _PC_ASYNC_IO: info->value = -1; // not supported err = EINVAL; break; case _PC_CHOWN_RESTRICTED: info->value = -1; // not supported err = EINVAL; break; case _PC_NO_TRUNC: info->value = 0; break; case _PC_PRIO_IO: info->value = 0; break; case _PC_SYNC_IO: info->value = 0; break; case _PC_VDISABLE: info->value = -1; // not supported err = EINVAL; break; default: err = EINVAL; break; } return err; } //========================================================================== // Filesystem operations // ------------------------------------------------------------------------- // ramfs_mount() // Process a mount request. This mainly creates a root for the // filesystem. static int ramfs_mount ( cyg_fstab_entry *fste, cyg_mtab_entry *mte ) { ramfs_node *root; int err; // Allocate a node to be the root of this filesystem and initialize it. root = alloc_node(__stat_mode_DIR|S_IRWXU|S_IRWXG|S_IRWXO); if( root == NULL ) return ENOSPC; // Add . and .. entries back to self. err = add_direntry( root, ".", 1, root ); if( err == ENOERR ) err = add_direntry( root, "..", 2, root ); if( err != ENOERR ) { free_node( root ); return err; } mte->root = (cyg_dir)root; return ENOERR; } // ------------------------------------------------------------------------- // ramfs_umount() // Unmount the filesystem. This will currently only succeed if the // filesystem is empty. static int ramfs_umount ( cyg_mtab_entry *mte ) { ramfs_node *root = (ramfs_node *)mte->root; // Check for open/inuse root if( root->refcnt != 0 ) return EBUSY; // Check that root directory is clear of extra links. if( root->nlink != 2 ) return EBUSY; // Just return it to free pool free_node( root ); // Clear root pointer mte->root = CYG_DIR_NULL; // That's all folks. return ENOERR; } // ------------------------------------------------------------------------- // ramfs_open() // Open a file for reading or writing. static int ramfs_open ( cyg_mtab_entry *mte, cyg_dir dir, const char *name, int mode, cyg_file *file ) { ramfs_dirsearch ds; ramfs_node *node = NULL; int err; init_dirsearch( &ds, (ramfs_node *)dir, name ); err = ramfs_find( &ds ); if( err == ENOENT ) { if( ds.last && (mode & O_CREAT) ) { // No node there, if the O_CREAT bit is set then we must // create a new one. The dir and name fields of the dirsearch // object will have been updated so we know where to put it. node = alloc_node( __stat_mode_REG|S_IRWXU|S_IRWXG|S_IRWXO); if( node == NULL ) return ENOSPC; err = add_direntry( ds.dir, ds.name, ds.namelen, node ); if( err != ENOERR ) { free_node( node ); return err; } err = ENOERR; } } else if( err == ENOERR ) { // The node exists. If the O_CREAT and O_EXCL bits are set, we // must fail the open. if( (mode & (O_CREAT|O_EXCL)) == (O_CREAT|O_EXCL) ) err = EEXIST; else node = ds.node; } if( err == ENOERR && (mode & O_TRUNC ) ) { // If the O_TRUNC bit is set we must clean out the file data. err = freebuffer_node( node ); node->size = 0; // Update file times node->ctime = node->mtime = cyg_timestamp(); } if( err != ENOERR ) return err; // Check that we actually have a file here if( S_ISDIR(node->mode) ) return EISDIR; node->refcnt++; // Count successful open // Initialize the file object file->f_flag |= mode & CYG_FILE_MODE_MASK; file->f_type = CYG_FILE_TYPE_FILE; file->f_ops = &ramfs_fileops; file->f_offset = (mode&O_APPEND) ? node->size : 0; file->f_data = (CYG_ADDRWORD)node; file->f_xops = 0; return ENOERR; } // ------------------------------------------------------------------------- // ramfs_unlink() // Remove a file link from its directory. static int ramfs_unlink ( cyg_mtab_entry *mte, cyg_dir dir, const char *name ) { ramfs_dirsearch ds; int err; init_dirsearch( &ds, (ramfs_node *)dir, name ); err = ramfs_find( &ds ); if( err != ENOERR ) return err; // Cannot unlink directories, use rmdir() instead if( S_ISDIR(ds.node->mode) ) return EPERM; // Delete it from its directory err = del_direntry( ds.dir, ds.name, ds.namelen ); return err; } // ------------------------------------------------------------------------- // ramfs_mkdir() // Create a new directory. static int ramfs_mkdir ( cyg_mtab_entry *mte, cyg_dir dir, const char *name ) { ramfs_dirsearch ds; ramfs_node *node = NULL; int err; init_dirsearch( &ds, (ramfs_node *)dir, name ); err = ramfs_find( &ds ); if( err == ENOENT ) { if( ds.last ) { // The entry does not exist, and it is the last element in // the pathname, so we can create it here. int doterr, dotdoterr, direrr; node = alloc_node( __stat_mode_DIR | S_IRWXU|S_IRWXG|S_IRWXO); if( node == NULL ) return ENOSPC; // Add "." and ".." entries. doterr = add_direntry( node, ".", 1, node ); dotdoterr = add_direntry( node, "..", 2, ds.dir ); // And add to parent directory. direrr = add_direntry( ds.dir, ds.name, ds.namelen, node ); // check for any errors in that... if( doterr+dotdoterr+direrr != ENOERR ) { // For each of the add_direntry() calls that succeeded, // we must now undo it. if( doterr == ENOERR ) del_direntry( node, ".", 1 ); else err = doterr; if( dotdoterr == ENOERR ) del_direntry( node, "..", 2 ); else err = dotdoterr; if( direrr == ENOERR ) del_direntry( ds.dir, ds.name, ds.namelen ); else err = direrr; // Free the data and the node itself. freebuffer_node( node ); free_node( node ); } else err = ENOERR; } // If this was not the last element, then and intermediate // directory does not exist. } else { // If there we no error, something already exists with that // name, so we cannot create another one. if( err == ENOERR ) err = EEXIST; } return err; } // ------------------------------------------------------------------------- // ramfs_rmdir() // Remove a directory. static int ramfs_rmdir ( cyg_mtab_entry *mte, cyg_dir dir, const char *name ) { ramfs_dirsearch ds; int err; init_dirsearch( &ds, (ramfs_node *)dir, name ); err = ramfs_find( &ds ); if( err != ENOERR ) return err; // Check that this is actually a directory. if( !S_ISDIR(ds.node->mode) ) return EPERM; // Delete the entry. This will adjust the link values // accordingly and if the directory is now unreferenced, // will cause it to be deleted. err = del_direntry( ds.dir, ds.name, ds.namelen ); return err; } // ------------------------------------------------------------------------- // ramfs_rename() // Rename a file/dir. static int ramfs_rename ( cyg_mtab_entry *mte, cyg_dir dir1, const char *name1, cyg_dir dir2, const char *name2 ) { ramfs_dirsearch ds1, ds2; int err; init_dirsearch( &ds1, (ramfs_node *)dir1, name1 ); err = ramfs_find( &ds1 ); if( err != ENOERR ) return err; init_dirsearch( &ds2, (ramfs_node *)dir2, name2 ); err = ramfs_find( &ds2 ); // Allow through renames to non-existent objects. if( ds2.last && err == ENOENT ) ds2.node = NULL, err = ENOERR; if( err != ENOERR ) return err; // Null rename, just return if( ds1.node == ds2.node ) return ENOERR; // First deal with any entry that is at the destination if( ds2.node ) { // Check that we are renaming like-for-like if( !S_ISDIR(ds1.node->mode) && S_ISDIR(ds2.node->mode) ) return EISDIR; if( S_ISDIR(ds1.node->mode) && !S_ISDIR(ds2.node->mode) ) return ENOTDIR; // Now delete the destination directory entry err = del_direntry( ds2.dir, ds2.name, ds2.namelen ); if( err != ENOERR ) return err; } // Now we know that there is no clashing node at the destination, // make a new direntry at the destination and delete the old entry // at the source. err = add_direntry( ds2.dir, ds2.name, ds2.namelen, ds1.node ); if( err == ENOERR ) err = del_direntry( ds1.dir, ds1.name, ds1.namelen ); // Update directory times if( err == ENOERR ) ds1.dir->ctime = ds1.dir->mtime = ds2.dir->ctime = ds2.dir->mtime = cyg_timestamp(); return err; } // ------------------------------------------------------------------------- // ramfs_link() // Make a new directory entry for a file. static int ramfs_link ( cyg_mtab_entry *mte, cyg_dir dir1, const char *name1, cyg_dir dir2, const char *name2, int type ) { ramfs_dirsearch ds1, ds2; int err; // Only do hard links for now in this filesystem if( type != CYG_FSLINK_HARD ) return EINVAL; init_dirsearch( &ds1, (ramfs_node *)dir1, name1 ); err = ramfs_find( &ds1 ); if( err != ENOERR ) return err; init_dirsearch( &ds2, (ramfs_node *)dir2, name2 ); err = ramfs_find( &ds2 ); // Don't allow links to existing objects if( err == ENOERR ) return EEXIST; // Allow through links to non-existing terminal objects if( ds2.last && err == ENOENT ) ds2.node = NULL, err = ENOERR; if( err != ENOERR ) return err; // Now we know that there is no existing node at the destination, // make a new direntry at the destination. err = add_direntry( ds2.dir, ds2.name, ds2.namelen, ds1.node ); if( err == ENOERR ) ds1.node->ctime = ds2.dir->ctime = ds2.dir->mtime = cyg_timestamp(); return err; } // ------------------------------------------------------------------------- // ramfs_opendir() // Open a directory for reading. static int ramfs_opendir ( cyg_mtab_entry *mte, cyg_dir dir, const char *name, cyg_file *file ) { ramfs_dirsearch ds; int err; init_dirsearch( &ds, (ramfs_node *)dir, name ); err = ramfs_find( &ds ); if( err != ENOERR ) return err; // check it is really a directory. if( !S_ISDIR(ds.node->mode) ) return ENOTDIR; ds.node->refcnt++; // Count successful open // Initialize the file object, setting the f_ops field to a // special set of file ops. file->f_type = CYG_FILE_TYPE_FILE; file->f_ops = &ramfs_dirops; file->f_offset = 0; file->f_data = (CYG_ADDRWORD)ds.node; file->f_xops = 0; return ENOERR; } // ------------------------------------------------------------------------- // ramfs_chdir() // Change directory support. static int ramfs_chdir ( cyg_mtab_entry *mte, cyg_dir dir, const char *name, cyg_dir *dir_out ) { if( dir_out != NULL ) { // This is a request to get a new directory pointer in // *dir_out. ramfs_dirsearch ds; int err; init_dirsearch( &ds, (ramfs_node *)dir, name ); err = ramfs_find( &ds ); if( err != ENOERR ) return err; // check it is a directory if( !S_ISDIR(ds.node->mode) ) return ENOTDIR; // Increment ref count to keep this directory in existent // while it is the current cdir. ds.node->refcnt++; // Pass it out *dir_out = (cyg_dir)ds.node; } else { // If no output dir is required, this means that the mte and // dir arguments are the current cdir setting and we should // forget this fact. ramfs_node *node = (ramfs_node *)dir; // Just decrement directory reference count. dec_refcnt( node ); } return ENOERR; } // ------------------------------------------------------------------------- // ramfs_stat() // Get struct stat info for named object. static int ramfs_stat ( cyg_mtab_entry *mte, cyg_dir dir, const char *name, struct stat *buf) { ramfs_dirsearch ds; int err; init_dirsearch( &ds, (ramfs_node *)dir, name ); err = ramfs_find( &ds ); if( err != ENOERR ) return err; // Fill in the status buf->st_mode = ds.node->mode; buf->st_ino = (ino_t)ds.node; buf->st_dev = 0; buf->st_nlink = ds.node->nlink; buf->st_uid = 0; buf->st_gid = 0; buf->st_size = ds.node->size; buf->st_atime = ds.node->atime; buf->st_mtime = ds.node->mtime; buf->st_ctime = ds.node->ctime; return err; } // ------------------------------------------------------------------------- // ramfs_getinfo() // Getinfo. Currently only support pathconf() and filesystem usage. static int ramfs_getinfo ( cyg_mtab_entry *mte, cyg_dir dir, const char *name, int key, void *buf, int len ) { ramfs_dirsearch ds; int err; init_dirsearch( &ds, (ramfs_node *)dir, name ); err = ramfs_find( &ds ); if( err != ENOERR ) return err; switch( key ) { case FS_INFO_CONF: err = ramfs_pathconf( ds.node, (struct cyg_pathconf_info *)buf ); break; #if defined(CYGSEM_FILEIO_BLOCK_USAGE) && defined(CYGPKG_FS_RAM_BLOCKS_ARRAY) // When using malloc for storage this does not make much // sense, so only implement this when using pre-allocated // blocks case FS_INFO_BLOCK_USAGE: { struct cyg_fs_block_usage *usage = (struct cyg_fs_block_usage *) buf; ramfs_block *b; usage->total_blocks = CYGNUM_FS_RAM_BLOCKS_ARRAY_SIZE; usage->free_blocks = 0; // Iterate over the free list to count its size b = block_free_list; while(b) { usage->free_blocks++; b=*(ramfs_block **)b; } usage->block_size = CYGNUM_RAMFS_BLOCK_SIZE; return ENOERR; } #endif default: err = EINVAL; } return err; } // ------------------------------------------------------------------------- // ramfs_setinfo() // Setinfo. Nothing to support here at present. static int ramfs_setinfo ( cyg_mtab_entry *mte, cyg_dir dir, const char *name, int key, void *buf, int len ) { // No setinfo keys supported at present return EINVAL; } //========================================================================== // File operations // ------------------------------------------------------------------------- // ramfs_fo_read() // Read data from the file. static int ramfs_fo_read (struct CYG_FILE_TAG *fp, struct CYG_UIO_TAG *uio) { ramfs_node *node = (ramfs_node *)fp->f_data; int i; off_t pos = fp->f_offset; ssize_t resid = uio->uio_resid; // Loop over the io vectors until there are none left for( i = 0; i < uio->uio_iovcnt; i++ ) { cyg_iovec *iov = &uio->uio_iov[i]; char *buf = (char *)iov->iov_base; off_t len = iov->iov_len; // Loop over each vector filling it with data from the file. while( len > 0 && pos < node->size ) { cyg_uint8 *fbuf; size_t bsize; off_t l = len; int err; // Get a pointer to the data at offset _pos_. err = findbuffer_node( node, pos, &fbuf, &bsize, false ); if( err != ENOERR ) return err; // adjust size to end of file if necessary if( l > node->size-pos ) l = node->size-pos; // adjust size to the amount of contiguous data we can see // at present. if( l > bsize ) l = bsize; if (fbuf) { // copy data out memcpy( buf, fbuf, l ); } else { // hole, so return zeros here. memset( buf, 0, l ); } // Update working vars len -= l; buf += l; pos += l; resid -= l; } } // We successfully read some data, update the node's access time // and update the file offset and transfer residue. node->atime = cyg_timestamp(); uio->uio_resid = resid; fp->f_offset = pos; return ENOERR; } // ------------------------------------------------------------------------- // ramfs_fo_write() // Write data to file. static int ramfs_fo_write (struct CYG_FILE_TAG *fp, struct CYG_UIO_TAG *uio) { ramfs_node *node = (ramfs_node *)fp->f_data; off_t pos = fp->f_offset; ssize_t resid = uio->uio_resid; int err = ENOERR; int i; // If the APPEND mode bit was supplied, force all writes to // the end of the file. if( fp->f_flag & CYG_FAPPEND ) pos = fp->f_offset = node->size; // Now loop over the iovecs until they are all done, or // we get an error. for( i = 0; i < uio->uio_iovcnt; i++ ) { cyg_iovec *iov = &uio->uio_iov[i]; char *buf = (char *)iov->iov_base; off_t len = iov->iov_len; // loop over the vector writing it to the file until it has // all been done. while( len > 0 ) { cyg_uint8 *fbuf; size_t bsize; off_t l = len; err = findbuffer_node( node, pos, &fbuf, &bsize, true ); // Stop writing if there is no more space in the file and // indicate end of data. if( err == ENOSPC ) break; if( err != ENOERR ) return err; // adjust size to this block if( l > bsize ) l = bsize; // copy data in memcpy( fbuf, buf, l ); // Update working vars len -= l; buf += l; pos += l; resid -= l; } } // We wrote some data successfully, update the modified and access // times of the node, increase its size appropriately, and update // the file offset and transfer residue. node->mtime = node->ctime = cyg_timestamp(); if( pos > node->size ) node->size = pos; uio->uio_resid = resid; fp->f_offset = pos; return err; } // ------------------------------------------------------------------------- // ramfs_fo_lseek() // Seek to a new file position. static int ramfs_fo_lseek (struct CYG_FILE_TAG *fp, off_t *apos, int whence ) { ramfs_node *node = (ramfs_node *)fp->f_data; off_t pos = *apos; switch( whence ) { case SEEK_SET: // Pos is already where we want to be. break; case SEEK_CUR: // Add pos to current offset. pos += fp->f_offset; break; case SEEK_END: // Add pos to file size. pos += node->size; break; default: return EINVAL; } // All OK, set fp offset and return new position. *apos = fp->f_offset = pos; return ENOERR; } // ------------------------------------------------------------------------- // ramfs_fo_ioctl() // Handle ioctls. Currently none are defined. static int ramfs_fo_ioctl (struct CYG_FILE_TAG *fp, CYG_ADDRWORD com, CYG_ADDRWORD data) { // No Ioctls currenly defined. return EINVAL; } // ------------------------------------------------------------------------- // ramfs_fo_fsync(). // Force the file out to data storage. static int ramfs_fo_fsync (struct CYG_FILE_TAG *fp, int mode ) { // Data is always permanently where it belongs, nothing to do // here. return ENOERR; } // ------------------------------------------------------------------------- // ramfs_fo_close() // Close a file. We just decrement the refcnt and let it go away if // that is all that is keeping it here. static int ramfs_fo_close (struct CYG_FILE_TAG *fp) { ramfs_node *node = (ramfs_node *)fp->f_data; dec_refcnt( node ); fp->f_data = 0; // zero data pointer return ENOERR; } // ------------------------------------------------------------------------- //ramfs_fo_fstat() // Get file status. static int ramfs_fo_fstat (struct CYG_FILE_TAG *fp, struct stat *buf ) { ramfs_node *node = (ramfs_node *)fp->f_data; // Fill in the status buf->st_mode = node->mode; buf->st_ino = (ino_t)node; buf->st_dev = 0; buf->st_nlink = node->nlink; buf->st_uid = 0; buf->st_gid = 0; buf->st_size = node->size; buf->st_atime = node->atime; buf->st_mtime = node->mtime; buf->st_ctime = node->ctime; return ENOERR; } // ------------------------------------------------------------------------- // ramfs_fo_getinfo() // Get info. Currently only supports fpathconf(). static int ramfs_fo_getinfo (struct CYG_FILE_TAG *fp, int key, void *buf, int len ) { ramfs_node *node = (ramfs_node *)fp->f_data; int err; switch( key ) { case FS_INFO_CONF: err = ramfs_pathconf( node, (struct cyg_pathconf_info *)buf ); break; default: err = EINVAL; } return err; } // ------------------------------------------------------------------------- // ramfs_fo_setinfo() // Set info. Nothing supported here. static int ramfs_fo_setinfo (struct CYG_FILE_TAG *fp, int key, void *buf, int len ) { // No setinfo key supported at present return ENOERR; } //========================================================================== // Directory operations // ------------------------------------------------------------------------- // ramfs_fo_dirread() // Read a single directory entry from a file. static int ramfs_fo_dirread (struct CYG_FILE_TAG *fp, struct CYG_UIO_TAG *uio) { ramfs_node *dir = (ramfs_node *)fp->f_data; off_t pos = fp->f_offset; int err = ENOERR; struct dirent *ent = (struct dirent *)uio->uio_iov[0].iov_base; char *nbuf = ent->d_name; int nlen = sizeof(ent->d_name)-1; off_t len = uio->uio_iov[0].iov_len; ramfs_dirent *d = NULL; cyg_uint8 *buf; size_t size; if( len < sizeof(struct dirent) ) return EINVAL; // look for a first name fragment while( pos < dir->size ) { err = findbuffer_node( dir, pos, &buf, &size, false ); if( err != ENOERR || size == 0) break; d = (ramfs_dirent *)buf; if( size < sizeof(ramfs_dirent) || !d->inuse || !d->first ) { pos += sizeof(ramfs_dirent); continue; } break; } // Check we have not exceeded the size of the directory. if( pos == dir->size ) return err; // Here we have the first fragment of a directory entry. for(;;) { int fraglen = d->fraglen; // adjust to allow for remaining space in dirent struct if( fraglen > nlen ) fraglen = nlen; memcpy( nbuf, d->name, fraglen); nbuf += fraglen; nlen -= fraglen; #ifdef CYGPKG_FS_RAM_RET_DIRENT_DTYPE ent->d_type = d->node->mode; #endif // if we hit the last entry, we have a successful transfer if( d->last || nlen == 0) break; // Otherwise move on to next entry in chain err = findbuffer_node( dir, d->next, &buf, &size, false ); if( err != ENOERR ) return err; d = (ramfs_dirent *)buf; } // A successful read. Terminate the entry name with a NUL, set the // residue and set the file offset to restart at the next // directory entry. *nbuf = '\0'; uio->uio_resid -= sizeof(struct dirent); fp->f_offset = pos+sizeof(ramfs_dirent); return ENOERR; } // ------------------------------------------------------------------------- // ramfs_fo_dirlseek() // Seek directory to start. static int ramfs_fo_dirlseek (struct CYG_FILE_TAG *fp, off_t *pos, int whence ) { // Only allow SEEK_SET to zero if( whence != SEEK_SET || *pos != 0) return EINVAL; *pos = fp->f_offset = 0; return ENOERR; } // ------------------------------------------------------------------------- // EOF ramfs.c
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