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[/] [or1k/] [trunk/] [rc203soc/] [sw/] [uClinux/] [fs/] [nfs/] [proc.c] - Rev 1628
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/* * linux/fs/nfs/proc.c * * Copyright (C) 1992, 1993, 1994 Rick Sladkey * * OS-independent nfs remote procedure call functions * * Tuned by Alan Cox <A.Cox@swansea.ac.uk> for >3K buffers * so at last we can have decent(ish) throughput off a * Sun server. * * Coding optimized and cleaned up by Florian La Roche. * Note: Error returns are optimized for NFS_OK, which isn't translated via * nfs_stat_to_errno(), but happens to be already the right return code. * * FixMe: We ought to define a sensible small max size for * things like getattr that are tiny packets and use the * old get_free_page stuff with it. * * Also, the code currently doesn't check the size of the packet, when * it decodes the packet. * * Feel free to fix it and mail me the diffs if it worries you. */ /* * Fixes: * Ion Badulescu <ionut@cs.columbia.edu> : FIFO's need special handling in NFSv2 */ /* * Defining NFS_PROC_DEBUG causes a lookup of a file named * "xyzzy" to toggle debugging. Just cd to an NFS-mounted * filesystem and type 'ls xyzzy' to turn on debugging. */ #if 0 #define NFS_PROC_DEBUG #endif #include <linux/param.h> #include <linux/sched.h> #include <linux/mm.h> #include <linux/malloc.h> #include <linux/nfs_fs.h> #include <linux/utsname.h> #include <linux/errno.h> #include <linux/string.h> #include <linux/in.h> #include <linux/pagemap.h> #include <asm/segment.h> #ifdef NFS_PROC_DEBUG static int proc_debug = 0; #define PRINTK(format, args...) \ do { \ if (proc_debug) \ printk(format , ## args); \ } while (0) #else /* !NFS_PROC_DEBUG */ #define PRINTK(format, args...) do ; while (0) #endif /* !NFS_PROC_DEBUG */ /* Mapping from NFS error code to "errno" error code. */ #define errno_NFSERR_IO EIO static int *nfs_rpc_header(int *p, int procedure, int ruid); static int *nfs_rpc_verify(int *p); static int nfs_stat_to_errno(int stat); /* * Our memory allocation and release functions. */ #define NFS_SLACK_SPACE 1024 /* Total overkill */ /* !!! Be careful, this constant is now also used in sock.c... We should easily convert to not using it anymore for most cases... */ static inline int *nfs_rpc_alloc(int size) { int *i; while (!(i = (int *)kmalloc(size+NFS_SLACK_SPACE,GFP_NFS))) { schedule(); } return i; } static inline void nfs_rpc_free(int *p) { kfree((void *)p); } /* * Here are a bunch of xdr encode/decode functions that convert * between machine dependent and xdr data formats. */ #define QUADLEN(len) (((len) + 3) >> 2) static inline int *xdr_encode_fhandle(int *p, struct nfs_fh *fhandle) { *((struct nfs_fh *) p) = *fhandle; return p + QUADLEN(sizeof(*fhandle)); } static inline int *xdr_decode_fhandle(int *p, struct nfs_fh *fhandle) { *fhandle = *((struct nfs_fh *) p); return p + QUADLEN(sizeof(*fhandle)); } static inline int *xdr_encode_string(int *p, const char *string) { int len = strlen(string); int quadlen = QUADLEN(len); p[quadlen] = 0; *p++ = htonl(len); memcpy(p, string, len); return p + quadlen; } static inline int *xdr_decode_string(int *p, char *string, unsigned int maxlen) { unsigned int len = ntohl(*p++); if (len > maxlen) return NULL; memcpy(string, p, len); string[len] = '\0'; return p + QUADLEN(len); } static inline int *xdr_decode_string2(int *p, char **string, unsigned int *len, unsigned int maxlen) { *len = ntohl(*p++); if (*len > maxlen) return NULL; *string = (char *) p; return p + QUADLEN(*len); } static inline int *xdr_encode_data(int *p, const char *data, int len) { int quadlen = QUADLEN(len); p[quadlen] = 0; *p++ = htonl(len); memcpy_fromfs(p, data, len); return p + quadlen; } static inline int *xdr_decode_data(int *p, char *data, int *lenp, int maxlen) { unsigned len = *lenp = ntohl(*p++); if (len > maxlen) return NULL; memcpy(data, p, len); return p + QUADLEN(len); } static int *xdr_decode_fattr(int *p, struct nfs_fattr *fattr) { fattr->type = (enum nfs_ftype) ntohl(*p++); fattr->mode = ntohl(*p++); fattr->nlink = ntohl(*p++); fattr->uid = ntohl(*p++); fattr->gid = ntohl(*p++); fattr->size = ntohl(*p++); fattr->blocksize = ntohl(*p++); fattr->rdev = ntohl(*p++); fattr->blocks = ntohl(*p++); fattr->fsid = ntohl(*p++); fattr->fileid = ntohl(*p++); fattr->atime.seconds = ntohl(*p++); fattr->atime.useconds = ntohl(*p++); fattr->mtime.seconds = ntohl(*p++); fattr->mtime.useconds = ntohl(*p++); fattr->ctime.seconds = ntohl(*p++); fattr->ctime.useconds = ntohl(*p++); if (fattr->type == NFCHR && fattr->rdev == NFS_FIFO_DEV) { fattr->type = NFFIFO; fattr->mode = (fattr->mode & ~S_IFMT) | S_IFIFO; fattr->rdev = 0; } return p; } static int *xdr_encode_sattr(int *p, struct nfs_sattr *sattr) { *p++ = htonl(sattr->mode); *p++ = htonl(sattr->uid); *p++ = htonl(sattr->gid); *p++ = htonl(sattr->size); *p++ = htonl(sattr->atime.seconds); *p++ = htonl(sattr->atime.useconds); *p++ = htonl(sattr->mtime.seconds); *p++ = htonl(sattr->mtime.useconds); return p; } static int *xdr_decode_entry(int *p, struct nfs_entry *entry) { entry->fileid = ntohl(*p++); if (!(p = xdr_decode_string(p, entry->name, NFS_MAXNAMLEN))) return NULL; entry->cookie = ntohl(*p++); entry->eof = 0; return p; } static int *xdr_decode_fsinfo(int *p, struct nfs_fsinfo *res) { res->tsize = ntohl(*p++); res->bsize = ntohl(*p++); res->blocks = ntohl(*p++); res->bfree = ntohl(*p++); res->bavail = ntohl(*p++); return p; } /* * One function for each procedure in the NFS protocol. */ int nfs_proc_getattr(struct nfs_server *server, struct nfs_fh *fhandle, struct nfs_fattr *fattr) { int *p, *p0; int status; int ruid = 0; PRINTK("NFS call getattr\n"); if (!(p0 = nfs_rpc_alloc(server->rsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_GETATTR, ruid); p = xdr_encode_fhandle(p, fhandle); if ((status = nfs_rpc_call(server, p0, p, server->rsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { p = xdr_decode_fattr(p, fattr); PRINTK("NFS reply getattr\n"); /* status = 0; */ } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply getattr failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_setattr(struct nfs_server *server, struct nfs_fh *fhandle, struct nfs_sattr *sattr, struct nfs_fattr *fattr) { int *p, *p0; int status; int ruid = 0; PRINTK("NFS call setattr\n"); if (!(p0 = nfs_rpc_alloc(server->wsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_SETATTR, ruid); p = xdr_encode_fhandle(p, fhandle); p = xdr_encode_sattr(p, sattr); if ((status = nfs_rpc_call(server, p0, p, server->wsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { p = xdr_decode_fattr(p, fattr); PRINTK("NFS reply setattr\n"); /* status = 0; */ } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply setattr failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_lookup(struct nfs_server *server, struct nfs_fh *dir, const char *name, struct nfs_fh *fhandle, struct nfs_fattr *fattr) { int *p, *p0; int status; int ruid = 0; PRINTK("NFS call lookup %s\n", name); #ifdef NFS_PROC_DEBUG if (!strcmp(name, "xyzzy")) proc_debug = 1 - proc_debug; #endif if (!(p0 = nfs_rpc_alloc(server->rsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_LOOKUP, ruid); p = xdr_encode_fhandle(p, dir); p = xdr_encode_string(p, name); if ((status = nfs_rpc_call(server, p0, p, server->rsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { p = xdr_decode_fhandle(p, fhandle); p = xdr_decode_fattr(p, fattr); PRINTK("NFS reply lookup\n"); /* status = 0; */ } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply lookup failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_readlink(struct nfs_server *server, struct nfs_fh *fhandle, int **p0, char **string, unsigned int *len, unsigned int maxlen) { int *p; int status, ruid = 0; PRINTK("NFS call readlink\n"); if (!(*p0 = nfs_rpc_alloc(server->rsize))) return -EIO; retry: p = nfs_rpc_header(*p0, NFSPROC_READLINK, ruid); p = xdr_encode_fhandle(p, fhandle); if ((status = nfs_rpc_call(server, *p0, p, server->rsize)) < 0) return status; if (!(p = nfs_rpc_verify(*p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { if (!(p = xdr_decode_string2(p, string, len, maxlen))) { printk("nfs_proc_readlink: giant pathname\n"); status = -errno_NFSERR_IO; } else /* status = 0, */ PRINTK("NFS reply readlink\n"); } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply readlink failed = %d\n", status); status = -nfs_stat_to_errno(status); } return status; } int nfs_proc_read(struct nfs_server *server, struct nfs_fh *fhandle, int offset, int count, char *data, struct nfs_fattr *fattr) { int *p, *p0; int status; int ruid = 0; int len; PRINTK("NFS call read %d @ %d\n", count, offset); if (!(p0 = nfs_rpc_alloc(server->rsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_READ, ruid); p = xdr_encode_fhandle(p, fhandle); *p++ = htonl(offset); *p++ = htonl(count); *p++ = htonl(count); /* traditional, could be any value */ if ((status = nfs_rpc_call(server, p0, p, server->rsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { p = xdr_decode_fattr(p, fattr); if (!(p = xdr_decode_data(p, data, &len, count))) { printk("nfs_proc_read: giant data size\n"); status = -errno_NFSERR_IO; } else { status = len; PRINTK("NFS reply read %d\n", len); } } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply read failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_read_request(struct rpc_ioreq *req, struct nfs_server *server, struct nfs_fh *fh, unsigned long offset, unsigned long count, __u32 *buf) { __u32 *p, *p0; int len; PRINTK("NFS reqst read %ld @ %ld\n", count, offset); if (!(p0 = nfs_rpc_alloc(NFS_SLACK_SPACE))) return -EIO; p = nfs_rpc_header(p0, NFSPROC_READ, 0); p = xdr_encode_fhandle(p, fh); *p++ = htonl(offset); *p++ = htonl(count); *p++ = htonl(count); /* traditional, could be any value */ req->rq_svec[0].iov_base = p0; req->rq_svec[0].iov_len = (p - p0) << 2; req->rq_slen = (p - p0) << 2; req->rq_snr = 1; len = (6 + 1 + 17 + 1); /* standard READ reply header */ req->rq_rvec[0].iov_base = p0; req->rq_rvec[0].iov_len = len << 2; req->rq_rvec[1].iov_base = buf; req->rq_rvec[1].iov_len = count; req->rq_rvec[2].iov_base = p0 + len; /* spill buffer */ req->rq_rvec[2].iov_len = (NFS_SLACK_SPACE - len) << 2; req->rq_rlen = count + NFS_SLACK_SPACE; req->rq_rnr = 3; req->rq_addr = &server->toaddr; req->rq_alen = sizeof(server->toaddr); return rpc_transmit(server->rsock, req); } int nfs_proc_read_reply(struct rpc_ioreq *req, struct nfs_fattr *fattr) { int status; __u32 *p0, *p; int count; p0 = (__u32 *) req->rq_rvec[0].iov_base; if (!(p = nfs_rpc_verify(p0))) { /* Tell the upper layers to retry */ status = -EAGAIN; /* status = -errno_NFSERR_IO; */ } else if ((status = ntohl(*p++)) == NFS_OK) { p = xdr_decode_fattr(p, fattr); count = ntohl(*p++); if (p != req->rq_rvec[2].iov_base) { /* unexpected RPC reply header size. punt. * fixme: move iovec contents to align data * on page boundary and adjust RPC header size * guess. */ status = -errno_NFSERR_IO; PRINTK("NFS reply read odd header size %d\n", (p - p0) << 2); } else { status = count; PRINTK("NFS reply read %d\n", count); } } else { PRINTK("NFS reply read failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_write(struct inode * inode, int offset, int count, const char *data, struct nfs_fattr *fattr) { int *p, *p0; int status; int ruid = 0; void * kdata; /* address of kernel copy */ struct nfs_server * server = NFS_SERVER(inode); struct nfs_fh *fhandle = NFS_FH(inode); PRINTK("NFS call write %d @ %d\n", count, offset); if (!(p0 = nfs_rpc_alloc(server->wsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_WRITE, ruid); p = xdr_encode_fhandle(p, fhandle); *p++ = htonl(offset); /* traditional, could be any value */ *p++ = htonl(offset); *p++ = htonl(count); /* traditional, could be any value */ kdata = (void *) (p+1); /* start of data in RPC buffer */ p = xdr_encode_data(p, data, count); if ((status = nfs_rpc_call(server, p0, p, server->wsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { update_vm_cache(inode, offset, kdata, count); p = xdr_decode_fattr(p, fattr); PRINTK("NFS reply write\n"); /* status = 0; */ } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply write failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_create(struct nfs_server *server, struct nfs_fh *dir, const char *name, struct nfs_sattr *sattr, struct nfs_fh *fhandle, struct nfs_fattr *fattr) { int *p, *p0; int status; int ruid = 0; PRINTK("NFS call create %s\n", name); if (!(p0 = nfs_rpc_alloc(server->wsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_CREATE, ruid); p = xdr_encode_fhandle(p, dir); p = xdr_encode_string(p, name); p = xdr_encode_sattr(p, sattr); if ((status = nfs_rpc_call(server, p0, p, server->wsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { p = xdr_decode_fhandle(p, fhandle); p = xdr_decode_fattr(p, fattr); PRINTK("NFS reply create\n"); /* status = 0; */ } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply create failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_remove(struct nfs_server *server, struct nfs_fh *dir, const char *name) { int *p, *p0; int status; int ruid = 0; PRINTK("NFS call remove %s\n", name); if (!(p0 = nfs_rpc_alloc(server->wsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_REMOVE, ruid); p = xdr_encode_fhandle(p, dir); p = xdr_encode_string(p, name); if ((status = nfs_rpc_call(server, p0, p, server->wsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { PRINTK("NFS reply remove\n"); /* status = 0; */ } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply remove failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_rename(struct nfs_server *server, struct nfs_fh *old_dir, const char *old_name, struct nfs_fh *new_dir, const char *new_name, int must_be_dir) { int *p, *p0; int status; int ruid = 0; /* * Disallow "rename()" with trailing slashes over NFS: getting * POSIX.1 behaviour is just too unlikely. */ if (must_be_dir) return -EINVAL; PRINTK("NFS call rename %s -> %s\n", old_name, new_name); if (!(p0 = nfs_rpc_alloc(server->wsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_RENAME, ruid); p = xdr_encode_fhandle(p, old_dir); p = xdr_encode_string(p, old_name); p = xdr_encode_fhandle(p, new_dir); p = xdr_encode_string(p, new_name); if ((status = nfs_rpc_call(server, p0, p, server->wsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { PRINTK("NFS reply rename\n"); /* status = 0; */ } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply rename failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_link(struct nfs_server *server, struct nfs_fh *fhandle, struct nfs_fh *dir, const char *name) { int *p, *p0; int status; int ruid = 0; PRINTK("NFS call link %s\n", name); if (!(p0 = nfs_rpc_alloc(server->wsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_LINK, ruid); p = xdr_encode_fhandle(p, fhandle); p = xdr_encode_fhandle(p, dir); p = xdr_encode_string(p, name); if ((status = nfs_rpc_call(server, p0, p, server->wsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { PRINTK("NFS reply link\n"); /* status = 0; */ } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply link failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_symlink(struct nfs_server *server, struct nfs_fh *dir, const char *name, const char *path, struct nfs_sattr *sattr) { int *p, *p0; int status; int ruid = 0; PRINTK("NFS call symlink %s -> %s\n", name, path); if (!(p0 = nfs_rpc_alloc(server->wsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_SYMLINK, ruid); p = xdr_encode_fhandle(p, dir); p = xdr_encode_string(p, name); p = xdr_encode_string(p, path); p = xdr_encode_sattr(p, sattr); if ((status = nfs_rpc_call(server, p0, p, server->wsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { PRINTK("NFS reply symlink\n"); /* status = 0; */ } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply symlink failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_mkdir(struct nfs_server *server, struct nfs_fh *dir, const char *name, struct nfs_sattr *sattr, struct nfs_fh *fhandle, struct nfs_fattr *fattr) { int *p, *p0; int status; int ruid = 0; PRINTK("NFS call mkdir %s\n", name); if (!(p0 = nfs_rpc_alloc(server->wsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_MKDIR, ruid); p = xdr_encode_fhandle(p, dir); p = xdr_encode_string(p, name); p = xdr_encode_sattr(p, sattr); if ((status = nfs_rpc_call(server, p0, p, server->wsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { p = xdr_decode_fhandle(p, fhandle); p = xdr_decode_fattr(p, fattr); PRINTK("NFS reply mkdir\n"); /* status = 0; */ } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply mkdir failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_rmdir(struct nfs_server *server, struct nfs_fh *dir, const char *name) { int *p, *p0; int status; int ruid = 0; PRINTK("NFS call rmdir %s\n", name); if (!(p0 = nfs_rpc_alloc(server->wsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_RMDIR, ruid); p = xdr_encode_fhandle(p, dir); p = xdr_encode_string(p, name); if ((status = nfs_rpc_call(server, p0, p, server->wsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { PRINTK("NFS reply rmdir\n"); /* status = 0; */ } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply rmdir failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_readdir(struct nfs_server *server, struct nfs_fh *fhandle, int cookie, int count, struct nfs_entry *entry) { int *p, *p0; int status; int ruid = 0; int i; int size; int eof; PRINTK("NFS call readdir %d @ %d\n", count, cookie); size = server->rsize; if (!(p0 = nfs_rpc_alloc(server->rsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_READDIR, ruid); p = xdr_encode_fhandle(p, fhandle); *p++ = htonl(cookie); *p++ = htonl(size); if ((status = nfs_rpc_call(server, p0, p, server->rsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { for (i = 0; i < count && *p++; i++) { if (!(p = xdr_decode_entry(p, entry++))) break; } if (!p) { printk("nfs_proc_readdir: giant filename\n"); status = -errno_NFSERR_IO; } else { eof = (i == count && !*p++ && *p++) || (i < count && *p++); if (eof && i) entry[-1].eof = 1; PRINTK("NFS reply readdir %d %s\n", i, eof ? "eof" : ""); status = i; } } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply readdir failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } int nfs_proc_statfs(struct nfs_server *server, struct nfs_fh *fhandle, struct nfs_fsinfo *res) { int *p, *p0; int status; int ruid = 0; PRINTK("NFS call statfs\n"); if (!(p0 = nfs_rpc_alloc(server->rsize))) return -EIO; retry: p = nfs_rpc_header(p0, NFSPROC_STATFS, ruid); p = xdr_encode_fhandle(p, fhandle); if ((status = nfs_rpc_call(server, p0, p, server->rsize)) < 0) { nfs_rpc_free(p0); return status; } if (!(p = nfs_rpc_verify(p0))) status = -errno_NFSERR_IO; else if ((status = ntohl(*p++)) == NFS_OK) { p = xdr_decode_fsinfo(p, res); PRINTK("NFS reply statfs\n"); /* status = 0; */ } else { if (!ruid && current->fsuid == 0 && current->uid != 0) { ruid = 1; goto retry; } PRINTK("NFS reply statfs failed = %d\n", status); status = -nfs_stat_to_errno(status); } nfs_rpc_free(p0); return status; } /* * Here are a few RPC-assist functions. */ int *rpc_header(int *p, int procedure, int program, int version, int uid, int gid, int *groups) { int *p1, *p2; int i; static int xid = 0; unsigned char *sys = (unsigned char *) system_utsname.nodename; if (xid == 0) { xid = CURRENT_TIME; xid ^= (sys[3]<<24) | (sys[2]<<16) | (sys[1]<<8) | sys[0]; } *p++ = htonl(++xid); *p++ = htonl(RPC_CALL); *p++ = htonl(RPC_VERSION); *p++ = htonl(program); *p++ = htonl(version); *p++ = htonl(procedure); *p++ = htonl(RPC_AUTH_UNIX); p1 = p++; *p++ = htonl(CURRENT_TIME); /* traditional, could be anything */ p = xdr_encode_string(p, (char *) sys); *p++ = htonl(uid); *p++ = htonl(gid); p2 = p++; for (i = 0; i < 16 && i < NGROUPS && groups[i] != NOGROUP; i++) *p++ = htonl(groups[i]); *p2 = htonl(i); *p1 = htonl((p - (p1 + 1)) << 2); *p++ = htonl(RPC_AUTH_NULL); *p++ = htonl(0); return p; } static int *nfs_rpc_header(int *p, int procedure, int ruid) { return rpc_header(p, procedure, NFS_PROGRAM, NFS_VERSION, (ruid ? current->uid : current->fsuid), current->egid, current->groups); } int *rpc_verify(int *p) { unsigned int n; p++; if ((n = ntohl(*p++)) != RPC_REPLY) { printk("nfs_rpc_verify: not an RPC reply: %x\n", n); return NULL; } if ((n = ntohl(*p++)) != RPC_MSG_ACCEPTED) { printk("nfs_rpc_verify: RPC call rejected: %d\n", n); return NULL; } switch (n = ntohl(*p++)) { case RPC_AUTH_NULL: case RPC_AUTH_UNIX: case RPC_AUTH_SHORT: break; default: printk("nfs_rpc_verify: bad RPC authentication type: %d\n", n); return NULL; } if ((n = ntohl(*p++)) > 400) { printk("nfs_rpc_verify: giant auth size\n"); return NULL; } p += QUADLEN(n); if ((n = ntohl(*p++)) != RPC_SUCCESS) { printk("nfs_rpc_verify: RPC call failed: %d\n", n); return NULL; } return p; } static int *nfs_rpc_verify(int *p) { return rpc_verify(p); } /* * We need to translate between nfs status return values and * the local errno values which may not be the same. */ static struct { int stat; int errno; } nfs_errtbl[] = { { NFS_OK, 0 }, { NFSERR_PERM, EPERM }, { NFSERR_NOENT, ENOENT }, { NFSERR_IO, errno_NFSERR_IO }, { NFSERR_NXIO, ENXIO }, { NFSERR_EAGAIN, EAGAIN }, { NFSERR_ACCES, EACCES }, { NFSERR_EXIST, EEXIST }, { NFSERR_XDEV, EXDEV }, { NFSERR_NODEV, ENODEV }, { NFSERR_NOTDIR, ENOTDIR }, { NFSERR_ISDIR, EISDIR }, { NFSERR_INVAL, EINVAL }, { NFSERR_FBIG, EFBIG }, { NFSERR_NOSPC, ENOSPC }, { NFSERR_ROFS, EROFS }, { NFSERR_NAMETOOLONG, ENAMETOOLONG }, { NFSERR_NOTEMPTY, ENOTEMPTY }, { NFSERR_DQUOT, EDQUOT }, { NFSERR_STALE, ESTALE }, #ifdef EWFLUSH { NFSERR_WFLUSH, EWFLUSH }, #endif { -1, EIO } }; static int nfs_stat_to_errno(int stat) { int i; for (i = 0; nfs_errtbl[i].stat != -1; i++) { if (nfs_errtbl[i].stat == stat) return nfs_errtbl[i].errno; } printk("nfs_stat_to_errno: bad nfs status return value: %d\n", stat); return nfs_errtbl[i].errno; }
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