FreeCalypso > hg > fc-magnetite
view src/cs/drivers/drv_app/ffs/board/ffs.c @ 638:cab2f315827e
FFS dev.c: added Spansion PL032J to the "generic" table
With the discovery of first GTM900 and then Tango, it now appears that
Openmoko was not the only manuf after all who kept TI's TCS211 firmware
largely intact (as opposed to changing it beyond all recognition like
Compal, Chi-Mei and BenQ did), thus we are now getting new "alien" targets
on which we reuse the original manuf's FFS with IMEI and RF calibration
tables as if it were native. On these targets we use the original
device table for FFS, even though we previously thought that it would
never apply to any target other than dsample, leonardo and gtamodem.
We have previously added Samsung K5L33xxCAM (a new kind of multi-ID device)
to the generic table to support its use in Huawei GTM900-B modules; now
we got news that some slightly older GTM900-B specimen used S71PL032J
instead, so we are now adding PL032J as well.
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Thu, 30 Jan 2020 17:45:48 +0000 |
parents | 945cf7f506b2 |
children |
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/****************************************************************************** * Flash File System (ffs) * Idea, design and coding by Mads Meisner-Jensen, mmj@ti.com * * ffs public API functions * * $Id: ffs.c 1.69.1.24.1.40 Thu, 08 Jan 2004 15:05:23 +0100 tsj $ * f ******************************************************************************/ #ifndef TARGET #include "ffs.cfg" #endif #if ((TARGET == 1) || (RIV_ENV== 1)) #include "ffs/board/task.h" #endif #if (TARGET == 0) #include <stdlib.h> #endif #include <string.h> #include <limits.h> #include "ffs/ffs.h" #include "ffs/board/core.h" #include "ffs/board/ffstrace.h" /****************************************************************************** * ******************************************************************************/ extern struct fs_s fs; // defined in core.c // These dummy defines and struct are only use to simulate FFS on the // PC. The ones that is used in target are located in task.h #if (TARGET == 0) struct ffs_blocking_s {int x; }; #define FFS_BLOCKING_CALL_BEGIN() int result; \ struct ffs_blocking_s fb; #define FFS_BLOCKING_CALL_END() #endif /****************************************************************************** * Create, Read and Write ******************************************************************************/ req_id_t ffs_file_write_b(const char *pathname, void *src, int size, ffs_options_t option, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { iref_t i, dir; char *name; effs_t error; int chunk_size, size_remaining, bytes_free; tw(tr(TR_FUNC, TrApi, "ffs_file_write('%s', 0x%x, %d, %d) ?\n", pathname, (int) src, size, option)); ttw(ttr(TTrApi, "ffs_file_write('%s', 0x%x, %d, %d) ?" NL, pathname, (int) src, size, option)); // TASKBEGIN effs_t FILE_WRITE(path=pathname, src=src, size=size, value16=option) iref_t i, dir; char *name; effs_t error; int chunk_size, size_remaining, bytes_free; if (fs.initerror) return fs.initerror; if (size < 0) return EFFS_INVALID; ffs_query(Q_BYTES_FREE, &bytes_free); if (bytes_free < size) return EFFS_NOSPACE; chunk_size = (size > fs.chunk_size_max ? fs.chunk_size_max : size); if ((i = object_lookup(pathname, &name, &dir)) < 0) { // Object not found, continue like fcreate() if (i != EFFS_NOTFOUND) return i; if (!is_open_option(option, FFS_O_CREATE)) return EFFS_NOTFOUND; journal_begin(0); if ((dir = object_create(name, src, chunk_size, -dir)) < 0) return dir; journal_end(OT_FILE); } else { // Object found, continue like fupdate() if (is_open_option(option, (FFS_O_CREATE)) && is_open_option(option, (FFS_O_EXCL))) return EFFS_EXISTS; if (get_fdi(i) >= 0) return EFFS_LOCKED; // Even though the ffs architecture allows to have data in // directory objects, we don't want to complicate matters, so we // return an error if (is_object(inode_addr(i), OT_DIR) && !(fs.flags & FS_DIR_DATA)) { return EFFS_NOTAFILE; } if ((i = is_readonly(i, pathname)) < 0) return i; // Save the segment (if any) in the global variable because this // global variable will be updated if the inode is going to be // relocated if an inode_reclaim() is triggeret by the object_create() fs.i_backup = segment_next(i); journal_begin(i); if ((dir = object_create(name, src, chunk_size, -dir)) < 0) return dir; // Do not link child - we are replacing the complete file! fs.link_child = 0; journal_end(0); // If any other segments exist then remove them FIXME: If we get a // power failure here then the remaining segments wil not be removed // before inode_reclaim() has been executed if (fs.i_backup > 0) if ((error = object_remove(fs.i_backup)) < 0) return error; } // Save dir in fs.i_backup because this will be updated if some of the // chunks below trigger a inode reclaim! fs.i_backup = dir; size_remaining = size - chunk_size; while (size_remaining > 0) { chunk_size = (size_remaining > fs.chunk_size_max ? fs.chunk_size_max : size_remaining); journal_begin(0); if ((i = segment_create((char*) src + size - size_remaining, chunk_size, fs.i_backup)) < 0) return i; journal_end(OT_SEGMENT); size_remaining -= chunk_size; } tw(tr_bstat()); return EFFS_OK; // TASKEND } // Note: ffs_fcreate() is deprecated and should not be used. Use // ffs_file_write(..., FFS_O_CREATE | FFS_O_EXCL) instead. effs_t ffs_fcreate(const char *pathname, void *src, int size) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_file_write_b(pathname, src, size, FFS_O_CREATE | FFS_O_EXCL, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_fcreate_nb(const char *pathname, void *src, int size, T_RV_RETURN *cp) { return ffs_file_write_b(pathname, src, size, FFS_O_CREATE | FFS_O_EXCL, cp, 0); } // Note: ffs_fupdate() is deprecated and should not be used. Use // ffs_file_write(...,FFS_O_TRUNC) instead. effs_t ffs_fupdate(const char *pathname, void *src, int size) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_file_write_b(pathname, src, size, FFS_O_TRUNC, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_fupdate_nb(const char *pathname, void *src, int size, T_RV_RETURN *cp) { return ffs_file_write_b(pathname, src, size, FFS_O_TRUNC, cp, 0); } // Note: ffs_fwrite() is deprecated and should not be used. Use // ffs_file_write(...,FFS_O_CREATE | FFS_O_TRUNC) instead. effs_t ffs_fwrite(const char *pathname, void *src, int size) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_file_write_b(pathname, src, size, FFS_O_CREATE | FFS_O_TRUNC, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_fwrite_nb(const char *pathname, void *src, int size, T_RV_RETURN *cp) { return ffs_file_write_b(pathname, src, size, FFS_O_CREATE | FFS_O_TRUNC, cp, 0); } effs_t ffs_file_write(const char *pathname, void *src, int size, ffs_options_t option) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_file_write_b(pathname, src, size, option, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_file_write_nb(const char *pathname, void *src, int size, ffs_options_t option, T_RV_RETURN *cp) { return ffs_file_write_b(pathname, src, size, option, cp, 0); } // Note important: ffs_fread() is deprecated and should not be used. Use // ffs_file_read() instead. int ffs_fread(const char *name, void *addr, int size) { return ffs_file_read(name, addr, size); } int ffs_file_read(const char *name, void *addr, int size) { int error; tw(tr(TR_BEGIN, TrApi, "file_read('%s', 0x%x, %d) {\n", name, (int) addr, size)); if ((error = ffs_begin()) == EFFS_OK) { error = file_read(name, addr, size); } tw(tr(TR_END, TrApi, "} %d\n", error)); return ffs_end(error); // number of bytes read } /****************************************************************************** * Stat, Symlink, Remove and Rename ******************************************************************************/ effs_t ffs_stat(const char *name, struct stat_s *stat) { iref_t i; tw(tr(TR_FUNC, TrApi, "ffs_stat('%s', ?) ?\n", name)); ttw(ttr(TTrApi, "ffs_stat('%s', ?) ?" NL, name)); if (name == NULL) return EFFS_BADNAME; if ((i = ffs_begin()) == EFFS_OK) { if ((i = object_stat(name, (struct xstat_s*) stat, 0, 0, 0)) > 0) i = EFFS_OK; } return ffs_end(i); } effs_t ffs_lstat(const char *name, struct stat_s *stat) { iref_t i; tw(tr(TR_FUNC, TrApi, "ffs_lstat('%s', ?) ?\n", name)); ttw(ttr(TTrApi, "ffs_lstat('%s', ?) ?" NL, name)); if ((i = ffs_begin()) == EFFS_OK) { if ((i = object_stat(name, (struct xstat_s*)stat, 1, 0, 0)) > 0) i = EFFS_OK; } return ffs_end(i); } effs_t ffs_xlstat(const char *name, struct xstat_s *stat) { iref_t i; tw(tr(TR_FUNC, TrApi, "ffs_xlstat('%s', ?) ?\n", name)); ttw(ttr(TTrApi, "ffs_xlstat('%s', ?) ?" NL, name)); if ((i = ffs_begin()) == EFFS_OK) { if ((i = object_stat(name, stat, 1, 0, 1)) > 0) i = EFFS_OK; } return ffs_end(i); } effs_t ffs_fstat(fd_t fdi, struct stat_s *stat) { iref_t i; tw(tr(TR_FUNC, TrApi, "ffs_fstat('%d', ?) ?\n", fdi)); ttw(ttr(TTrApi, "ffs_fstat('%d', ?) ?" NL, fdi)); if ((i = ffs_begin()) == EFFS_OK) { if ((i = object_stat( 0, (struct xstat_s*) stat, 0, fdi, 0)) > 0) i = EFFS_OK; } return ffs_end(i); } req_id_t ffs_symlink_b(const char *pathname, const char *src, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { iref_t i, dir; char *name; int size; tw(tr(TR_FUNC, TrApi, "ffs_symlink('%s', '%s') ?\n", pathname, src)); ttw(ttr(TTrApi, "ffs_symlink('%s', '%s') ?" NL, pathname, src)); // TASKBEGIN effs_t SYMLINK(path=pathname, src=src) iref_t i, dir; int size; char *name; if (fs.initerror) return fs.initerror; if (src == NULL) return EFFS_BADNAME; i = object_lookup(pathname, &name, &dir); if (i > 0) return EFFS_EXISTS; if (i != EFFS_NOTFOUND) return i; size = ffs_strlen(src) + 1; // include null-terminator journal_begin(0); if ((i = object_create(name, src, size, -dir)) < 0) return i; journal_end(OT_LINK); tw(tr_bstat()); return EFFS_OK; // TASKEND } effs_t ffs_symlink(const char *pathname, const char *actualpath) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_symlink_b(pathname, actualpath, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_symlink_nb(const char *pathname, const char *src, T_RV_RETURN *cp) { return ffs_symlink_b(pathname, src, cp, 0); } int ffs_readlink(const char *name, char *addr, int size) { int error; tw(tr(TR_FUNC, TrApi, "ffs_readlink('%s')\n", name)); if ((error = ffs_begin()) == EFFS_OK) { error = object_read(name, addr, size, 1); } return ffs_end(error); } req_id_t ffs_remove_b(const char *pathname, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { iref_t i; tw(tr(TR_FUNC, TrApi, "ffs_remove('%s')\n", pathname)); ttw(ttr(TTrApi, "ffs_remove('%s') ?" NL, pathname)); // TASKBEGIN effs_t REMOVE(path=pathname) iref_t i; if (fs.initerror) return fs.initerror; if ((i = object_lookup_once(pathname, 0, 0)) < 0) return i; if (get_fdi(i) >= 0) return EFFS_LOCKED; if ((i = is_readonly(i, pathname)) < 0) return i; if ((i = object_remove(i)) < 0) return i; tw(tr_bstat()); return EFFS_OK; // TASKEND } effs_t ffs_remove(const char *pathname) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_remove_b(pathname, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_remove_nb(const char *pathname, T_RV_RETURN *cp) { return ffs_remove_b(pathname, cp, 0); } req_id_t ffs_fcontrol_b(const char *pathname, int8 action, int param, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { iref_t i; tw(tr(TR_FUNC, TrApi, "ffs_fcontrol('%s', %d, 0x%x) ?\n", pathname, action, param)); ttw(ttr(TTrApi, "ffs_fcontrol('%s', %d, 0x%x) ?" NL, pathname, action, param)); // TASKBEGIN effs_t FCONTROL(path=pathname, value16=action, size=param) iref_t i; if (fs.initerror) return fs.initerror; if (pathname == NULL) return EFFS_BADNAME; if ((i = ffs_strcmp(pathname, "/dev/ffs")) != 0) { if ((i = object_lookup_once(pathname, 0, 0)) < 0) return i; if ((i = is_readonly(i, pathname)) < 0) return i; } if ((i = object_control(i, action, param)) < 0) return i; tw(tr_bstat()); return EFFS_OK; // TASKEND } effs_t ffs_fcontrol(const char *pathname, int8 action, int param) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_fcontrol_b(pathname, action, param, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_fcontrol_nb(const char *pathname, int8 action, int param, T_RV_RETURN *cp) { return ffs_fcontrol_b(pathname, action, param, cp, 0); } req_id_t ffs_rename_b(const char *pathname, const char *newname, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { iref_t i, oldi, dir; char *name; struct inode_s *ip; tw(tr(TR_FUNC, TrApi, "ffs_rename('%s', '%s') ?\n", pathname, newname)); ttw(ttr(TTrApi, "ffs_rename('%s', '%s') ?" NL, pathname, newname)); // TASKBEGIN effs_t RENAME(path=pathname, src=newname) iref_t i, oldi, dir; char *name; struct inode_s *ip; if (fs.initerror) return fs.initerror; // pathname MUST exist, not be open and MUST be writable if ((oldi = object_lookup_once(pathname, 0, 0)) < 0) return oldi; if ((oldi = is_readonly(oldi, pathname)) < 0) return oldi; if (get_fdi(oldi) >= 0) return EFFS_LOCKED; journal_begin(oldi); if ((i = object_lookup_once(newname, &name, &dir)) < 0) { if (i != EFFS_NOTFOUND) return i; } else { // newname obj exist ip = inode_addr(oldi); if (is_object(ip, OT_FILE)) { // is old obj a file? if ((i = is_readonly(i, newname)) < 0) return i; ip = inode_addr(i); if (!is_object(ip, OT_FILE)) // newname MUST be a file return EFFS_NOTAFILE; fs.journal.repli = i; } else return EFFS_EXISTS; } if ((i = object_rename(oldi, name, -dir)) < 0) return i; journal_end(0); tw(tr_bstat()); return EFFS_OK; // TASKEND } effs_t ffs_rename(const char *pathname, const char *newname) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_rename_b(pathname, newname, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_rename_nb(const char *pathname, const char *newname, T_RV_RETURN *cp) { return ffs_rename_b(pathname, newname, cp, 0); } /****************************************************************************** * Directory Operations ******************************************************************************/ // All directory operations are more or less similar to unix // semantics. req_id_t ffs_mkdir_b(const char *pathname, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { iref_t i, dir; char *name; tw(tr(TR_FUNC, TrApi, "ffs_mkdir('%s')\n", pathname)); ttw(ttr(TTrApi, "ffs_mkdir('%s') ?" NL, pathname)); // TASKBEGIN effs_t MKDIR(path=pathname) iref_t i, dir; char *name; if (fs.initerror) return fs.initerror; i = object_lookup(pathname, &name, &dir); if (i > 0) return EFFS_EXISTS; if (i != EFFS_NOTFOUND) return i; journal_begin(0); if ((i = object_create(name, 0, 0, -dir)) < 0) return i; journal_end(OT_DIR); tw(tr_bstat()); return EFFS_OK; // TASKEND } effs_t ffs_mkdir(const char *pathname) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_mkdir_b(pathname, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_mkdir_nb(const char *pathname, T_RV_RETURN *cp) { return ffs_mkdir_b(pathname, cp, 0); } int ffs_opendir(const char *name, struct dir_s *dir) { int i; tw(tr(TR_FUNC, TrApi, "ffs_opendir('%s', ?)\n", name)); ttw(ttr(TTrApi, "ffs_opendir('%s', ?) ?" NL, name)); if (dir == NULL) return EFFS_INVALID; if ((i = ffs_begin()) == EFFS_OK) { if ((i = dir_open(name)) >= 0) { dir->this = i; dir->index = i; // Now count the number of entries in the directory dir_traverse(-i, (iref_t *) &i); } } return ffs_end(i); } int ffs_readdir(struct dir_s *dir, char *name, int size) { iref_t i; tw(tr(TR_BEGIN, TrApi, "ffs_readdir(?, ?, ?) {\n")); ttw(ttr(TTrApi, "ffs_readdir(?, ?, ?) ?" NL)); if (dir == NULL || name == NULL || size < 0) { tw(tr(TR_END, TrApi, "} %d\n", EFFS_INVALID)); return EFFS_INVALID; } if ((i = ffs_begin()) == EFFS_OK) { if ((i = dir_next(dir->this, dir->index, name, size))) dir->index = i; } tw(tr(TR_END, TrApi, "} ('%s') %d\n", name, i)); return ffs_end(i); } /****************************************************************************** * Preformat and Format ******************************************************************************/ // Note that we do NOT call ffs_begin() because it will just return // EFFS_NOFORMAT! req_id_t ffs_format_b(const char *name, uint16 magic, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { effs_t i; tw(tr(TR_BEGIN, TrApi, "ffs_format('%s', 0x%x) {\n", name, magic)); ttw(ttr(TTrApi, "ffs_format('%s', 0x%x) ?" NL, name, magic)); // TASKBEGIN effs_t FORMAT(path=name, size=magic) iref_t i; if (magic != 0x2BAD) { tw(tr(TR_END, TrApi, "} %d\n", EFFS_INVALID)); return EFFS_INVALID; } if (name == NULL) { name = "/ffs-5.54"; } if (*name != '/') { tw(tr(TR_END, TrApi, "} %d\n", EFFS_BADNAME)); return EFFS_BADNAME; } if ((i = is_formattable(1)) < 0) { tw(tr(TR_END, TrApi, "} %d\n", i)); return i; } if ((i = fs_format(name)) < 0) return i; tw(tr(TR_END, TrApi, "} %d\n", i)); tw(tr_bstat()); return EFFS_OK; // TASKEND } effs_t ffs_format(const char *name, uint16 magic) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_format_b(name, magic, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_format_nb(const char *name, uint16 magic, T_RV_RETURN *cp) { return ffs_format_b(name, magic, cp, 0); } req_id_t ffs_preformat_b(uint16 magic, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { effs_t i; tw(tr(TR_BEGIN, TrApi, "ffs_preformat(0x%x) {\n", magic)); ttw(ttr(TTrApi, "ffs_preformat(0x%x) ?" NL, magic)); // TASKBEGIN effs_t PREFORMAT(path="/", size=magic) effs_t i; if (magic != 0xDEAD) { tw(tr(TR_END, TrApi, "} %d\n", EFFS_INVALID)); return EFFS_INVALID; } if (!ffs_is_modifiable("")) { tw(tr(TR_END, TrApi, "} %d\n", EFFS_ACCESS)); return EFFS_ACCESS; } if ((i = is_formattable(0)) < 0) { tw(tr(TR_END, TrApi, "} %d\n", i)); return i; } if ((i = fs_preformat()) < 0) return i; tw(tr(TR_END, TrApi, "} %d\n", i)); tw(tr_bstat()); return EFFS_OK; // TASKEND } effs_t ffs_preformat(uint16 magic) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_preformat_b(magic, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_preformat_nb(uint16 magic, T_RV_RETURN *cp) { return ffs_preformat_b(magic, cp, 0); } /****************************************************************************** * Open, Read, Write, Close ******************************************************************************/ req_id_t ffs_open_b(const char *pathname, ffs_options_t option, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { iref_t i, dir, dummy; char *name; fd_t other_fdi, fdi = 0; int error; struct inode_s *ip; tw(tr(TR_FUNC, TrApi, "ffs_open('%s', 0x%x) ?\n", pathname, option)); ttw(ttr(TTrApi, "ffs_open('%s', 0x%x) ?" NL, pathname, option)); // TASKBEGIN fd_t OPEN(path=pathname, value16=option) iref_t i, dir, dummy; char *name; fd_t other_fdi, fdi = 0; int error; struct inode_s *ip; if (fs.initerror) return fs.initerror; // Minimum one of the flags RD or WR must be specifyed if (!is_open_option(option, FFS_O_RDONLY) && !is_open_option(option, FFS_O_WRONLY)) return EFFS_INVALID; // RDONLY must not be combined with any other options if not together // with WR! if (is_open_option(option, FFS_O_RDONLY) && !is_open_option(option, FFS_O_WRONLY)) if (!(option == FFS_O_RDONLY)) return EFFS_INVALID; for (fdi = 0; fdi < fs.fd_max; fdi++) { // Find free fd if (fs.fd[fdi].options == 0) { break; } } if (fdi >= fs.fd_max) return EFFS_NUMFD; // Too many open files in system i = object_lookup(pathname, &name, &dir); if (i < 0 && i != EFFS_NOTFOUND) return i; // Open one file several times in RD is okay but only one time in WR if (i != EFFS_NOTFOUND && (other_fdi = get_fdi(i)) >= 0) { if (is_open_option(fs.fd[other_fdi].options, FFS_O_WRONLY) || is_open_option(option, FFS_O_WRONLY)) return EFFS_LOCKED; } // Init default values fs.fd[fdi].fp = fs.fd[fdi].size = fs.fd[fdi].wfp = fs.fd[fdi].dirty = 0; if (i == EFFS_NOTFOUND) { if (is_open_option(option, (FFS_O_CREATE | FFS_O_WRONLY))) { if ((error = is_filename(name)) < 0) return error; // Create segmenthead journal_begin(0); if ((i = object_create(name, 0, 0, -dir)) < 0) return i; journal_end(OT_FILE); tw(tr_bstat()); fs.fd[fdi].seghead = i; } else return EFFS_NOTFOUND; } else { if (is_open_option(option, FFS_O_WRONLY)) { if (is_open_option(option, (FFS_O_CREATE | FFS_O_EXCL))) return EFFS_EXISTS; if ((i = is_readonly(i, pathname)) < 0) return i; } ip = inode_addr(i); if (is_object(ip, OT_DIR)) return EFFS_NOTAFILE; if (is_open_option(option, FFS_O_TRUNC)) { // Save the segment (if any) in the global variable because this // global variable will be updated if the inode is relocated by // an inode_reclaim() triggeret by object_create() fs.i_backup = segment_next(i); // Replace old seghead with a new and remove all old segments journal_begin(i); if ((i = object_create(name, 0, 0, -dir)) < 0) return i; // Do not link child fs.link_child = 0; journal_end(0); // If any further segments exist then remove them now if (fs.i_backup > 0) if ((error = object_remove(fs.i_backup)) < 0) return error; tw(tr_bstat()); } else { // Get total size of the file. fs.fd[fdi].size = segfile_seek(i, INT_MAX, &dummy, 0); } if (is_open_option(option, FFS_O_APPEND)) { fs.fd[fdi].fp = fs.fd[fdi].size; } } if (is_open_option(option, FFS_O_WRONLY)) { #if (TARGET == 1) if ((fs.fd[fdi].buf = (char *) target_malloc(fs.fd_buf_size)) == 0) return EFFS_MEMORY; #else if ((fs.fd[fdi].buf = malloc(fs.fd_buf_size)) == 0) return EFFS_MEMORY; #endif } // Save data in file descriptor fs.fd[fdi].seghead = i; fs.fd[fdi].options = option; return fdi + FFS_FD_OFFSET; // TASKEND } fd_t ffs_open(const char *pathname, ffs_options_t option) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_open_b(pathname, option, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_open_nb(const char *pathname, ffs_options_t option, T_RV_RETURN *cp) { return ffs_open_b(pathname, option, cp, 0); } req_id_t ffs_close_b(fd_t fdi, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { int error; tw(tr(TR_FUNC, TrApi, "ffs_close(%d) ?\n", fdi)); ttw(ttr(TTrApi, "ffs_close(%d) ?" NL, fdi)); // TASKBEGIN effs_t CLOSE(fdi=fdi) iref_t i; int error; if (fs.initerror) return fs.initerror; fdi -= FFS_FD_OFFSET; if (!is_fd_valid(fdi)) return EFFS_BADFD; if (is_open_option(fs.fd[fdi].options, FFS_O_WRONLY )) { if ((error = datasync(fdi)) < 0) return error; #if (TARGET == 1) target_free(fs.fd[fdi].buf); #else free(fs.fd[fdi].buf); #endif } // Clear all data in file descriptor fs.fd[fdi].seghead = 0; fs.fd[fdi].options = fs.fd[fdi].fp = 0; return EFFS_OK; // TASKEND } effs_t ffs_close(fd_t fdi) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_close_b(fdi, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_close_nb(fd_t fdi, T_RV_RETURN *cp) { return ffs_close_b( fdi, cp, 0); } req_id_t ffs_write_b(fd_t fdi, void *src, int amount, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { effs_t error; iref_t i; int size_remaining, fp_offset; int size, size_done; offset_t chunk_offset; tw(tr(TR_BEGIN, TrApi, "ffs_write_b(%d, 0x%x, %d) ?{\n", fdi, src, amount)); ttw(ttr(TTrApi, "ffs_write_b(%d, 0x%x, %d) ?" NL, fdi, src, amount)); // TASKBEGIN int WRITE(fdi=fdi, src=src, size=amount) effs_t error; iref_t i; int size_remaining, fp_offset; int size, size_done; offset_t chunk_offset; if (fs.initerror) return fs.initerror; if (amount < 0 || src == NULL) return EFFS_INVALID; fdi -= FFS_FD_OFFSET; if (!is_fd_valid(fdi)) return EFFS_BADFD; if (!is_open_option(fs.fd[fdi].options, FFS_O_WRONLY )) return EFFS_INVALID; // not opened with write flag // If FFS_O_APPEEND is specified move fp to eof if (is_open_option(fs.fd[fdi].options, FFS_O_APPEND )) fs.fd[fdi].fp = fs.fd[fdi].size; // If fp has been moved outside the write buf (by a read) then flush the // write buffer. if (fs.fd[fdi].fp >= (fs.fd[fdi].wfp + fs.chunk_size_max)) { if ((error = datasync(fdi)) < 0) return error; } size_done = 0; size_remaining = amount; do { if (!fs.fd[fdi].dirty ) { // Buffer is not dirty so find the chunk that fp points to. segfile_seek(fs.fd[fdi].seghead, fs.fd[fdi].fp, &i, &chunk_offset); if ((fs.fd[fdi].size == fs.fd[fdi].fp && chunk_offset == fs.chunk_size_max) || fs.fd[fdi].size == 0 ) { // End of file and last chunk is full or empty seghead. fs.fd[fdi].wfp = fs.fd[fdi].size; fs.fd[fdi].wch = 0; // Create new chunk (not update). } else { // Work on this chunk and update it later by datasyns segment_read(i, fs.fd[fdi].buf, fs.fd_buf_size, 0); fs.fd[fdi].wfp = fs.fd[fdi].fp - chunk_offset; fs.fd[fdi].wch = i; } } fs.fd[fdi].dirty = 1; fp_offset = fs.fd[fdi].fp - fs.fd[fdi].wfp; // Fill the buffer to max or just add the rest size = fs.chunk_size_max - fp_offset; if (size_remaining <= fs.chunk_size_max - fp_offset) size = size_remaining; tw(tr(TR_FUNC, TrApi, "Copy data to buffer (size: %d)\n", size)); memcpy(fs.fd[fdi].buf + fp_offset, (uint8*)src + size_done, size); fs.fd[fdi].fp += size; if (fs.fd[fdi].fp > fs.fd[fdi].size) fs.fd[fdi].size = fs.fd[fdi].fp; size_done += size; // FIXME: remove size_done or size_remaining size_remaining -= size; // If wrbuf is full (size = chunk_size_max) so create a chunk. if (fs.fd[fdi].fp >= (fs.fd[fdi].wfp + fs.chunk_size_max)) { if ((error = datasync(fdi)) < 0) return error; } } while(size_remaining > 0); tw(tr(TR_END, TrApi, "} %d\n", amount)); return amount; // TASKEND } int ffs_write(fd_t fdi, void *src, int amount) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_write_b(fdi, src, amount, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_write_nb(fd_t fdi, void *src, int amount, T_RV_RETURN *cp) { tw(tr(TR_FUNC, TrApi, "ffs_write_nb(%d, 0x%x, %d) ?\n", fdi, src, amount)); return ffs_write_b(fdi, src, amount, cp, 0); } int ffs_read(fd_t fdi, void *src, int size) { int error; tw(tr(TR_BEGIN, TrApi, "ffs_read(%d, 0x%x, %d) {\n", fdi, src, size)); ttw(ttr(TTrApi, "ffs_read(%d, 0x%x, %d) ?" NL, fdi, src, size)); if ((error = ffs_begin()) == EFFS_OK) { error = stream_read(fdi - FFS_FD_OFFSET, src, size); } tw(tr(TR_END, TrApi, "} %d\n", error)); return ffs_end(error); // number of bytes read } // The seek function will not allow the file offset to be set beyond the end // of the existing data in the file or the final offset to be negative. req_id_t ffs_seek_b(fd_t fdi, int offset, int whence, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { effs_t error; int fp_new; tw(tr(TR_FUNC, TrApi, "ffs_seek(%d, %d, %d) ?\n", fdi, offset, whence)); ttw(ttr(TTrApi, "ffs_seek(%d, %d, %d) ?" NL, fdi, offset, whence)); // TASKBEGIN int SEEK(fdi=fdi, size=offset, value16=whence) effs_t error; iref_t i; int fp_new, foffset; if (fs.initerror) return fs.initerror; fdi -= FFS_FD_OFFSET; if (!is_fd_valid(fdi)) return EFFS_BADFD; switch(whence) { case FFS_SEEK_SET: if (offset < 0 || offset > fs.fd[fdi].size) return EFFS_INVALID; fp_new = offset; break; case FFS_SEEK_CUR: if (fs.fd[fdi].fp + offset < 0 || fs.fd[fdi].fp + offset > fs.fd[fdi].size) return EFFS_INVALID; fp_new = fs.fd[fdi].fp + offset; break; case FFS_SEEK_END: if (offset > 0 || fs.fd[fdi].size < -offset) return EFFS_INVALID; fp_new = (offset + fs.fd[fdi].size); break; default: return EFFS_INVALID; } if (!is_offset_in_buf(fp_new, fdi)) if ((error = datasync(fdi)) < 0) return error; return fs.fd[fdi].fp = fp_new; // TASKEND } int ffs_seek(fd_t fdi, int offset, int whence) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_seek_b(fdi, offset, whence, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_seek_nb(fd_t fdi, int offset, int whence, T_RV_RETURN *cp) { return ffs_seek_b(fdi, offset, whence, cp, 0); } req_id_t ffs_truncate_b(const char *path, offset_t length, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { tw(tr(TR_FUNC, TrApi, "ffs_truncate('%s', %d) \n", path, length)); ttw(ttr(TTrApi, "ffs_ftruncate('%s', %d) ?" NL, path, length)); // TASKBEGIN effs_t TRUNC(path=path, size=length) iref_t i; if (fs.initerror) return fs.initerror; if (path == NULL) return EFFS_BADNAME; return object_truncate(path, -1, length); // TASKEND } effs_t ffs_truncate(const char *path, offset_t length) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_truncate_b(path, length, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_truncate_nb(const char *path, offset_t length, T_RV_RETURN *cp) { return ffs_truncate_b(path, length, cp, 0); } req_id_t ffs_ftruncate_b(fd_t fdi, offset_t length, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { tw(tr(TR_FUNC, TrApi, "ffs_ftruncate(%d, %d) \n", fdi, length)); ttw(ttr(TTrApi, "ffs_ftruncate(%d, %d) ?" NL, fdi, length)); // TASKBEGIN effs_t FTRUNC(fdi=fdi, size=length) iref_t i; if (fs.initerror) return fs.initerror; return object_truncate(0, fdi - FFS_FD_OFFSET, length); // TASKEND } effs_t ffs_ftruncate(fd_t fdi, offset_t length) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_ftruncate_b(fdi, length, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_ftruncate_nb(fd_t fdi, offset_t length, T_RV_RETURN *cp) { return ffs_ftruncate_b(fdi, length, cp, 0); } req_id_t ffs_fdatasync_b(fd_t fdi, T_RV_RETURN *cp, struct ffs_blocking_s *fb) { tw(tr(TR_FUNC, TrApi, "ffs_fdatasync(%d) \n", fdi)); ttw(ttr(TTrApi, "ffs_fdatasync(%d) ?" NL, fdi)); // TASKBEGIN effs_t FDATASYNC(fdi=fdi) effs_t error; if (fs.initerror) return fs.initerror; return datasync(fdi - FFS_FD_OFFSET); // TASKEND } effs_t ffs_fdatasync(fd_t fdi) { FFS_BLOCKING_CALL_BEGIN(); result = ffs_fdatasync_b(fdi, 0, &fb); FFS_BLOCKING_CALL_END(); return result; } req_id_t ffs_fdatasync_nb(fd_t fdi, T_RV_RETURN *cp) { return ffs_fdatasync_b(fdi, cp, 0); }