/* * Unix SMB/CIFS implementation. * Samba VFS module for GPFS filesystem * Copyright (C) Christian Ambach 2006 * Copyright (C) Christof Schmitt 2015 * Major code contributions by Chetan Shringarpure * and Gomati Mohanan * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, see . */ #include "includes.h" #include "smbd/smbd.h" #include "include/smbprofile.h" #include "modules/non_posix_acls.h" #include "libcli/security/security.h" #include "nfs4_acls.h" #include "system/filesys.h" #include "auth.h" #include "lib/util/tevent_unix.h" #include "lib/util/gpfswrap.h" #include #include #include "lib/crypto/gnutls_helpers.h" #undef DBGC_CLASS #define DBGC_CLASS DBGC_VFS #ifndef GPFS_GETACL_NATIVE #define GPFS_GETACL_NATIVE 0x00000004 #endif struct gpfs_config_data { struct smbacl4_vfs_params nfs4_params; bool sharemodes; bool leases; bool hsm; bool syncio; bool winattr; bool ftruncate; bool getrealfilename; bool dfreequota; bool acl; bool settimes; bool recalls; struct { bool gpfs_fstat_x; } pathref_ok; }; struct gpfs_fsp_extension { bool offline; }; static inline unsigned int gpfs_acl_flags(gpfs_acl_t *gacl) { if (gacl->acl_level == GPFS_ACL_LEVEL_V4FLAGS) { return gacl->v4Level1.acl_flags; } return 0; } static inline gpfs_ace_v4_t *gpfs_ace_ptr(gpfs_acl_t *gacl, unsigned int i) { if (gacl->acl_level == GPFS_ACL_LEVEL_V4FLAGS) { return &gacl->v4Level1.ace_v4[i]; } return &gacl->ace_v4[i]; } static unsigned int vfs_gpfs_access_mask_to_allow(uint32_t access_mask) { unsigned int allow = GPFS_SHARE_NONE; if (access_mask & (FILE_WRITE_DATA|FILE_APPEND_DATA)) { allow |= GPFS_SHARE_WRITE; } if (access_mask & (FILE_READ_DATA|FILE_EXECUTE)) { allow |= GPFS_SHARE_READ; } return allow; } static unsigned int vfs_gpfs_share_access_to_deny(uint32_t share_access) { unsigned int deny = GPFS_DENY_NONE; if (!(share_access & FILE_SHARE_WRITE)) { deny |= GPFS_DENY_WRITE; } if (!(share_access & FILE_SHARE_READ)) { deny |= GPFS_DENY_READ; } /* * GPFS_DENY_DELETE can only be set together with either * GPFS_DENY_WRITE or GPFS_DENY_READ. */ if ((deny & (GPFS_DENY_WRITE|GPFS_DENY_READ)) && !(share_access & FILE_SHARE_DELETE)) { deny |= GPFS_DENY_DELETE; } return deny; } static int set_gpfs_sharemode(files_struct *fsp, uint32_t access_mask, uint32_t share_access) { unsigned int allow = GPFS_SHARE_NONE; unsigned int deny = GPFS_DENY_NONE; int result; if (access_mask == 0) { DBG_DEBUG("Clearing file system share mode.\n"); } else { allow = vfs_gpfs_access_mask_to_allow(access_mask); deny = vfs_gpfs_share_access_to_deny(share_access); } DBG_DEBUG("access_mask=0x%x, allow=0x%x, share_access=0x%x, " "deny=0x%x\n", access_mask, allow, share_access, deny); result = gpfswrap_set_share(fsp_get_io_fd(fsp), allow, deny); if (result == 0) { return 0; } if (errno == EACCES) { DBG_NOTICE("GPFS share mode denied for %s/%s.\n", fsp->conn->connectpath, fsp->fsp_name->base_name); } else if (errno == EPERM) { DBG_ERR("Samba requested GPFS sharemode for %s/%s, but the " "GPFS file system is not configured accordingly. " "Configure file system with mmchfs -D nfs4 or " "set gpfs:sharemodes=no in Samba.\n", fsp->conn->connectpath, fsp->fsp_name->base_name); } else { DBG_ERR("gpfs_set_share failed: %s\n", strerror(errno)); } return result; } static int vfs_gpfs_kernel_flock(vfs_handle_struct *handle, files_struct *fsp, uint32_t share_access, uint32_t access_mask) { struct gpfs_config_data *config; int ret = 0; START_PROFILE(syscall_kernel_flock); SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return -1); if(!config->sharemodes) { return 0; } /* * A named stream fsp will have the basefile open in the fsp * fd, so lacking a distinct fd for the stream we have to skip * kernel_flock and set_gpfs_sharemode for stream. */ if (is_named_stream(fsp->fsp_name)) { DBG_NOTICE("Not requesting GPFS sharemode on stream: %s/%s\n", fsp->conn->connectpath, fsp_str_dbg(fsp)); return 0; } kernel_flock(fsp_get_io_fd(fsp), share_access, access_mask); ret = set_gpfs_sharemode(fsp, access_mask, share_access); END_PROFILE(syscall_kernel_flock); return ret; } static int vfs_gpfs_close(vfs_handle_struct *handle, files_struct *fsp) { struct gpfs_config_data *config; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return -1); if (config->sharemodes && (fsp->fsp_flags.kernel_share_modes_taken)) { /* * Always clear GPFS sharemode in case the actual * close gets deferred due to outstanding POSIX locks * (see fd_close_posix) */ int ret = gpfswrap_set_share(fsp_get_io_fd(fsp), 0, 0); if (ret != 0) { DBG_ERR("Clearing GPFS sharemode on close failed for " " %s/%s: %s\n", fsp->conn->connectpath, fsp->fsp_name->base_name, strerror(errno)); } } return SMB_VFS_NEXT_CLOSE(handle, fsp); } static int lease_type_to_gpfs(int leasetype) { if (leasetype == F_RDLCK) { return GPFS_LEASE_READ; } if (leasetype == F_WRLCK) { return GPFS_LEASE_WRITE; } return GPFS_LEASE_NONE; } static int vfs_gpfs_setlease(vfs_handle_struct *handle, files_struct *fsp, int leasetype) { struct gpfs_config_data *config; int ret=0; START_PROFILE(syscall_linux_setlease); SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return -1); ret = linux_set_lease_sighandler(fsp_get_io_fd(fsp)); if (ret == -1) { goto failure; } if (config->leases) { int gpfs_lease_type = lease_type_to_gpfs(leasetype); int saved_errno = 0; /* * Ensure the lease owner is root to allow * correct delivery of lease-break signals. */ become_root(); ret = gpfswrap_set_lease(fsp_get_io_fd(fsp), gpfs_lease_type); if (ret < 0) { saved_errno = errno; } unbecome_root(); if (saved_errno != 0) { errno = saved_errno; } } failure: END_PROFILE(syscall_linux_setlease); return ret; } static int vfs_gpfs_get_real_filename(struct vfs_handle_struct *handle, const struct smb_filename *path, const char *name, TALLOC_CTX *mem_ctx, char **found_name) { int result; char *full_path = NULL; char *to_free = NULL; char real_pathname[PATH_MAX+1], tmpbuf[PATH_MAX]; size_t full_path_len; int buflen; bool mangled; struct gpfs_config_data *config; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return -1); if (!config->getrealfilename) { return SMB_VFS_NEXT_GET_REAL_FILENAME(handle, path, name, mem_ctx, found_name); } mangled = mangle_is_mangled(name, handle->conn->params); if (mangled) { return SMB_VFS_NEXT_GET_REAL_FILENAME(handle, path, name, mem_ctx, found_name); } full_path_len = full_path_tos(path->base_name, name, tmpbuf, sizeof(tmpbuf), &full_path, &to_free); if (full_path_len == -1) { errno = ENOMEM; return -1; } buflen = sizeof(real_pathname) - 1; result = gpfswrap_get_realfilename_path(full_path, real_pathname, &buflen); TALLOC_FREE(to_free); if ((result == -1) && (errno == ENOSYS)) { return SMB_VFS_NEXT_GET_REAL_FILENAME( handle, path, name, mem_ctx, found_name); } if (result == -1) { DEBUG(10, ("smbd_gpfs_get_realfilename_path returned %s\n", strerror(errno))); return -1; } /* * GPFS does not necessarily null-terminate the returned path * but instead returns the buffer length in buflen. */ if (buflen < sizeof(real_pathname)) { real_pathname[buflen] = '\0'; } else { real_pathname[sizeof(real_pathname)-1] = '\0'; } DEBUG(10, ("smbd_gpfs_get_realfilename_path: %s/%s -> %s\n", path->base_name, name, real_pathname)); name = strrchr_m(real_pathname, '/'); if (name == NULL) { errno = ENOENT; return -1; } *found_name = talloc_strdup(mem_ctx, name+1); if (*found_name == NULL) { errno = ENOMEM; return -1; } return 0; } static void sd2gpfs_control(uint16_t control, struct gpfs_acl *gacl) { unsigned int gpfs_aclflags = 0; control &= SEC_DESC_DACL_PROTECTED | SEC_DESC_SACL_PROTECTED | SEC_DESC_DACL_AUTO_INHERITED | SEC_DESC_SACL_AUTO_INHERITED | SEC_DESC_DACL_DEFAULTED | SEC_DESC_SACL_DEFAULTED | SEC_DESC_DACL_PRESENT | SEC_DESC_SACL_PRESENT; gpfs_aclflags = control << 8; if (!(control & SEC_DESC_DACL_PRESENT)) gpfs_aclflags |= ACL4_FLAG_NULL_DACL; if (!(control & SEC_DESC_SACL_PRESENT)) gpfs_aclflags |= ACL4_FLAG_NULL_SACL; gacl->acl_level = GPFS_ACL_LEVEL_V4FLAGS; gacl->v4Level1.acl_flags = gpfs_aclflags; } static uint16_t gpfs2sd_control(unsigned int gpfs_aclflags) { uint16_t control = gpfs_aclflags >> 8; control &= SEC_DESC_DACL_PROTECTED | SEC_DESC_SACL_PROTECTED | SEC_DESC_DACL_AUTO_INHERITED | SEC_DESC_SACL_AUTO_INHERITED | SEC_DESC_DACL_DEFAULTED | SEC_DESC_SACL_DEFAULTED | SEC_DESC_DACL_PRESENT | SEC_DESC_SACL_PRESENT; control |= SEC_DESC_SELF_RELATIVE; return control; } static void gpfs_dumpacl(int level, struct gpfs_acl *gacl) { gpfs_aclCount_t i; if (gacl==NULL) { DEBUG(0, ("gpfs acl is NULL\n")); return; } DEBUG(level, ("len: %d, level: %d, version: %d, nace: %d, " "control: %x\n", gacl->acl_len, gacl->acl_level, gacl->acl_version, gacl->acl_nace, gpfs_acl_flags(gacl))); for(i=0; iacl_nace; i++) { struct gpfs_ace_v4 *gace = gpfs_ace_ptr(gacl, i); DEBUG(level, ("\tace[%d]: type:%d, flags:0x%x, mask:0x%x, " "iflags:0x%x, who:%u\n", i, gace->aceType, gace->aceFlags, gace->aceMask, gace->aceIFlags, gace->aceWho)); } } static int gpfs_getacl_with_capability(const char *fname, int flags, void *buf) { int ret, saved_errno; set_effective_capability(DAC_OVERRIDE_CAPABILITY); ret = gpfswrap_getacl(fname, flags, buf); saved_errno = errno; drop_effective_capability(DAC_OVERRIDE_CAPABILITY); errno = saved_errno; return ret; } /* * get the ACL from GPFS, allocated on the specified mem_ctx * internally retries when initial buffer was too small * * caller needs to cast result to either * raw = yes: struct gpfs_opaque_acl * raw = no: struct gpfs_acl * */ static void *vfs_gpfs_getacl(TALLOC_CTX *mem_ctx, const char *fname, const bool raw, const gpfs_aclType_t type) { void *aclbuf; size_t size = 512; int ret, flags; unsigned int *len; size_t struct_size; bool use_capability = false; again: aclbuf = talloc_zero_size(mem_ctx, size); if (aclbuf == NULL) { errno = ENOMEM; return NULL; } if (raw) { struct gpfs_opaque_acl *buf = (struct gpfs_opaque_acl *) aclbuf; buf->acl_type = type; flags = GPFS_GETACL_NATIVE; len = (unsigned int *) &(buf->acl_buffer_len); struct_size = sizeof(struct gpfs_opaque_acl); } else { struct gpfs_acl *buf = (struct gpfs_acl *) aclbuf; buf->acl_type = type; buf->acl_level = GPFS_ACL_LEVEL_V4FLAGS; flags = GPFS_GETACL_STRUCT; len = &(buf->acl_len); /* reserve space for control flags in gpfs 3.5 and beyond */ struct_size = sizeof(struct gpfs_acl) + sizeof(unsigned int); } /* set the length of the buffer as input value */ *len = size; if (use_capability) { ret = gpfs_getacl_with_capability(fname, flags, aclbuf); } else { ret = gpfswrap_getacl(fname, flags, aclbuf); if ((ret != 0) && (errno == EACCES)) { DBG_DEBUG("Retry with DAC capability for %s\n", fname); use_capability = true; ret = gpfs_getacl_with_capability(fname, flags, aclbuf); } } if ((ret != 0) && (errno == ENOSPC)) { /* * get the size needed to accommodate the complete buffer * * the value returned only applies to the ACL blob in the * struct so make sure to also have headroom for the first * struct members by adding room for the complete struct * (might be a few bytes too much then) */ size = *len + struct_size; talloc_free(aclbuf); DEBUG(10, ("Increasing ACL buffer size to %zu\n", size)); goto again; } if (ret != 0) { DEBUG(5, ("smbd_gpfs_getacl failed with %s\n", strerror(errno))); talloc_free(aclbuf); return NULL; } return aclbuf; } /* Tries to get nfs4 acls and returns SMB ACL allocated. * On failure returns 1 if it got non-NFSv4 ACL to prompt * retry with POSIX ACL checks. * On failure returns -1 if there is system (GPFS) error, check errno. * Returns 0 on success */ static int gpfs_get_nfs4_acl(TALLOC_CTX *mem_ctx, const char *fname, struct SMB4ACL_T **ppacl) { gpfs_aclCount_t i; struct gpfs_acl *gacl = NULL; DEBUG(10, ("gpfs_get_nfs4_acl invoked for %s\n", fname)); /* Get the ACL */ gacl = (struct gpfs_acl*) vfs_gpfs_getacl(talloc_tos(), fname, false, 0); if (gacl == NULL) { DEBUG(9, ("gpfs_getacl failed for %s with %s\n", fname, strerror(errno))); if (errno == ENODATA) { /* * GPFS returns ENODATA for snapshot * directories. Retry with POSIX ACLs check. */ return 1; } return -1; } if (gacl->acl_type != GPFS_ACL_TYPE_NFS4) { DEBUG(10, ("Got non-nfsv4 acl\n")); /* Retry with POSIX ACLs check */ talloc_free(gacl); return 1; } *ppacl = smb_create_smb4acl(mem_ctx); if (gacl->acl_level == GPFS_ACL_LEVEL_V4FLAGS) { uint16_t control = gpfs2sd_control(gpfs_acl_flags(gacl)); smbacl4_set_controlflags(*ppacl, control); } DEBUG(10, ("len: %d, level: %d, version: %d, nace: %d, control: %x\n", gacl->acl_len, gacl->acl_level, gacl->acl_version, gacl->acl_nace, gpfs_acl_flags(gacl))); for (i=0; iacl_nace; i++) { struct gpfs_ace_v4 *gace = gpfs_ace_ptr(gacl, i); SMB_ACE4PROP_T smbace = { 0 }; DEBUG(10, ("type: %d, iflags: %x, flags: %x, mask: %x, " "who: %d\n", gace->aceType, gace->aceIFlags, gace->aceFlags, gace->aceMask, gace->aceWho)); if (gace->aceIFlags & ACE4_IFLAG_SPECIAL_ID) { smbace.flags |= SMB_ACE4_ID_SPECIAL; switch (gace->aceWho) { case ACE4_SPECIAL_OWNER: smbace.who.special_id = SMB_ACE4_WHO_OWNER; break; case ACE4_SPECIAL_GROUP: smbace.who.special_id = SMB_ACE4_WHO_GROUP; break; case ACE4_SPECIAL_EVERYONE: smbace.who.special_id = SMB_ACE4_WHO_EVERYONE; break; default: DEBUG(8, ("invalid special gpfs id %d " "ignored\n", gace->aceWho)); continue; /* don't add it */ } } else { if (gace->aceFlags & ACE4_FLAG_GROUP_ID) smbace.who.gid = gace->aceWho; else smbace.who.uid = gace->aceWho; } /* remove redundant deny entries */ if (i > 0 && gace->aceType == SMB_ACE4_ACCESS_DENIED_ACE_TYPE) { struct gpfs_ace_v4 *prev = gpfs_ace_ptr(gacl, i - 1); if (prev->aceType == SMB_ACE4_ACCESS_ALLOWED_ACE_TYPE && prev->aceFlags == gace->aceFlags && prev->aceIFlags == gace->aceIFlags && (gace->aceMask & prev->aceMask) == 0 && gace->aceWho == prev->aceWho) { /* it's redundant - skip it */ continue; } } smbace.aceType = gace->aceType; smbace.aceFlags = gace->aceFlags; smbace.aceMask = gace->aceMask; smb_add_ace4(*ppacl, &smbace); } talloc_free(gacl); return 0; } static NTSTATUS gpfsacl_fget_nt_acl(vfs_handle_struct *handle, files_struct *fsp, uint32_t security_info, TALLOC_CTX *mem_ctx, struct security_descriptor **ppdesc) { struct SMB4ACL_T *pacl = NULL; int result; struct gpfs_config_data *config; TALLOC_CTX *frame = talloc_stackframe(); NTSTATUS status; *ppdesc = NULL; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return NT_STATUS_INTERNAL_ERROR); if (!config->acl) { status = SMB_VFS_NEXT_FGET_NT_ACL(handle, fsp, security_info, mem_ctx, ppdesc); TALLOC_FREE(frame); return status; } result = gpfs_get_nfs4_acl(frame, fsp->fsp_name->base_name, &pacl); if (result == 0) { status = smb_fget_nt_acl_nfs4(fsp, &config->nfs4_params, security_info, mem_ctx, ppdesc, pacl); TALLOC_FREE(frame); return status; } if (result > 0) { DEBUG(10, ("retrying with posix acl...\n")); status = posix_fget_nt_acl(fsp, security_info, mem_ctx, ppdesc); TALLOC_FREE(frame); return status; } TALLOC_FREE(frame); /* GPFS ACL was not read, something wrong happened, error code is set in errno */ return map_nt_error_from_unix(errno); } static bool vfs_gpfs_nfs4_ace_to_gpfs_ace(SMB_ACE4PROP_T *nfs4_ace, struct gpfs_ace_v4 *gace, uid_t owner_uid) { gace->aceType = nfs4_ace->aceType; gace->aceFlags = nfs4_ace->aceFlags; gace->aceMask = nfs4_ace->aceMask; if (nfs4_ace->flags & SMB_ACE4_ID_SPECIAL) { switch(nfs4_ace->who.special_id) { case SMB_ACE4_WHO_EVERYONE: gace->aceIFlags = ACE4_IFLAG_SPECIAL_ID; gace->aceWho = ACE4_SPECIAL_EVERYONE; break; case SMB_ACE4_WHO_OWNER: /* * With GPFS it is not possible to deny ACL or * attribute access to the owner. Setting an * ACL with such an entry is not possible. * Denying ACL or attribute access for the * owner through a named ACL entry can be * stored in an ACL, it is just not effective. * * Map this case to a named entry to allow at * least setting this ACL, which will be * enforced by the smbd permission check. Do * not do this for an inheriting OWNER entry, * as this represents a CREATOR OWNER ACE. The * remaining limitation is that CREATOR OWNER * cannot deny ACL or attribute access. */ if (!nfs_ace_is_inherit(nfs4_ace) && nfs4_ace->aceType == SMB_ACE4_ACCESS_DENIED_ACE_TYPE && nfs4_ace->aceMask & (SMB_ACE4_READ_ATTRIBUTES| SMB_ACE4_WRITE_ATTRIBUTES| SMB_ACE4_READ_ACL| SMB_ACE4_WRITE_ACL)) { gace->aceIFlags = 0; gace->aceWho = owner_uid; } else { gace->aceIFlags = ACE4_IFLAG_SPECIAL_ID; gace->aceWho = ACE4_SPECIAL_OWNER; } break; case SMB_ACE4_WHO_GROUP: gace->aceIFlags = ACE4_IFLAG_SPECIAL_ID; gace->aceWho = ACE4_SPECIAL_GROUP; break; default: DBG_WARNING("Unsupported special_id %d\n", nfs4_ace->who.special_id); return false; } return true; } gace->aceIFlags = 0; gace->aceWho = (nfs4_ace->aceFlags & SMB_ACE4_IDENTIFIER_GROUP) ? nfs4_ace->who.gid : nfs4_ace->who.uid; return true; } static struct gpfs_acl *vfs_gpfs_smbacl2gpfsacl(TALLOC_CTX *mem_ctx, files_struct *fsp, struct SMB4ACL_T *smbacl, bool controlflags) { struct gpfs_acl *gacl; gpfs_aclLen_t gacl_len; struct SMB4ACE_T *smbace; gacl_len = offsetof(gpfs_acl_t, ace_v4) + sizeof(unsigned int) + smb_get_naces(smbacl) * sizeof(gpfs_ace_v4_t); gacl = (struct gpfs_acl *)TALLOC_SIZE(mem_ctx, gacl_len); if (gacl == NULL) { DEBUG(0, ("talloc failed\n")); errno = ENOMEM; return NULL; } gacl->acl_level = GPFS_ACL_LEVEL_BASE; gacl->acl_version = GPFS_ACL_VERSION_NFS4; gacl->acl_type = GPFS_ACL_TYPE_NFS4; gacl->acl_nace = 0; /* change later... */ if (controlflags) { gacl->acl_level = GPFS_ACL_LEVEL_V4FLAGS; sd2gpfs_control(smbacl4_get_controlflags(smbacl), gacl); } for (smbace=smb_first_ace4(smbacl); smbace!=NULL; smbace = smb_next_ace4(smbace)) { struct gpfs_ace_v4 *gace = gpfs_ace_ptr(gacl, gacl->acl_nace); SMB_ACE4PROP_T *aceprop = smb_get_ace4(smbace); bool add_ace; add_ace = vfs_gpfs_nfs4_ace_to_gpfs_ace(aceprop, gace, fsp->fsp_name->st.st_ex_uid); if (!add_ace) { continue; } gacl->acl_nace++; } gacl->acl_len = (char *)gpfs_ace_ptr(gacl, gacl->acl_nace) - (char *)gacl; return gacl; } static bool gpfsacl_process_smbacl(vfs_handle_struct *handle, files_struct *fsp, struct SMB4ACL_T *smbacl) { int ret; struct gpfs_acl *gacl; TALLOC_CTX *mem_ctx = talloc_tos(); gacl = vfs_gpfs_smbacl2gpfsacl(mem_ctx, fsp, smbacl, true); if (gacl == NULL) { /* out of memory */ return False; } ret = gpfswrap_putacl(fsp->fsp_name->base_name, GPFS_PUTACL_STRUCT | GPFS_ACL_SAMBA, gacl); if ((ret != 0) && (errno == EINVAL)) { DEBUG(10, ("Retry without nfs41 control flags\n")); talloc_free(gacl); gacl = vfs_gpfs_smbacl2gpfsacl(mem_ctx, fsp, smbacl, false); if (gacl == NULL) { /* out of memory */ return False; } ret = gpfswrap_putacl(fsp->fsp_name->base_name, GPFS_PUTACL_STRUCT | GPFS_ACL_SAMBA, gacl); } if (ret != 0) { DEBUG(8, ("gpfs_putacl failed with %s\n", strerror(errno))); gpfs_dumpacl(8, gacl); return False; } DEBUG(10, ("gpfs_putacl succeeded\n")); return True; } static NTSTATUS gpfsacl_set_nt_acl_internal(vfs_handle_struct *handle, files_struct *fsp, uint32_t security_info_sent, const struct security_descriptor *psd) { struct gpfs_acl *acl; NTSTATUS result = NT_STATUS_ACCESS_DENIED; acl = (struct gpfs_acl*) vfs_gpfs_getacl(talloc_tos(), fsp->fsp_name->base_name, false, 0); if (acl == NULL) { return map_nt_error_from_unix(errno); } if (acl->acl_version == GPFS_ACL_VERSION_NFS4) { struct gpfs_config_data *config; if (lp_parm_bool(fsp->conn->params->service, "gpfs", "refuse_dacl_protected", false) && (psd->type&SEC_DESC_DACL_PROTECTED)) { DEBUG(2, ("Rejecting unsupported ACL with DACL_PROTECTED bit set\n")); talloc_free(acl); return NT_STATUS_NOT_SUPPORTED; } SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return NT_STATUS_INTERNAL_ERROR); result = smb_set_nt_acl_nfs4(handle, fsp, &config->nfs4_params, security_info_sent, psd, gpfsacl_process_smbacl); } else { /* assume POSIX ACL - by default... */ result = set_nt_acl(fsp, security_info_sent, psd); } talloc_free(acl); return result; } static NTSTATUS gpfsacl_fset_nt_acl(vfs_handle_struct *handle, files_struct *fsp, uint32_t security_info_sent, const struct security_descriptor *psd) { struct gpfs_config_data *config; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return NT_STATUS_INTERNAL_ERROR); if (!config->acl) { return SMB_VFS_NEXT_FSET_NT_ACL(handle, fsp, security_info_sent, psd); } return gpfsacl_set_nt_acl_internal(handle, fsp, security_info_sent, psd); } static SMB_ACL_T gpfs2smb_acl(const struct gpfs_acl *pacl, TALLOC_CTX *mem_ctx) { SMB_ACL_T result; gpfs_aclCount_t i; result = sys_acl_init(mem_ctx); if (result == NULL) { errno = ENOMEM; return NULL; } result->count = pacl->acl_nace; result->acl = talloc_realloc(result, result->acl, struct smb_acl_entry, result->count); if (result->acl == NULL) { TALLOC_FREE(result); errno = ENOMEM; return NULL; } for (i=0; iacl_nace; i++) { struct smb_acl_entry *ace = &result->acl[i]; const struct gpfs_ace_v1 *g_ace = &pacl->ace_v1[i]; DEBUG(10, ("Converting type %d id %lu perm %x\n", (int)g_ace->ace_type, (unsigned long)g_ace->ace_who, (int)g_ace->ace_perm)); switch (g_ace->ace_type) { case GPFS_ACL_USER: ace->a_type = SMB_ACL_USER; ace->info.user.uid = (uid_t)g_ace->ace_who; break; case GPFS_ACL_USER_OBJ: ace->a_type = SMB_ACL_USER_OBJ; break; case GPFS_ACL_GROUP: ace->a_type = SMB_ACL_GROUP; ace->info.group.gid = (gid_t)g_ace->ace_who; break; case GPFS_ACL_GROUP_OBJ: ace->a_type = SMB_ACL_GROUP_OBJ; break; case GPFS_ACL_OTHER: ace->a_type = SMB_ACL_OTHER; break; case GPFS_ACL_MASK: ace->a_type = SMB_ACL_MASK; break; default: DEBUG(10, ("Got invalid ace_type: %d\n", g_ace->ace_type)); TALLOC_FREE(result); errno = EINVAL; return NULL; } ace->a_perm = 0; ace->a_perm |= (g_ace->ace_perm & ACL_PERM_READ) ? SMB_ACL_READ : 0; ace->a_perm |= (g_ace->ace_perm & ACL_PERM_WRITE) ? SMB_ACL_WRITE : 0; ace->a_perm |= (g_ace->ace_perm & ACL_PERM_EXECUTE) ? SMB_ACL_EXECUTE : 0; DEBUGADD(10, ("Converted to %d perm %x\n", ace->a_type, ace->a_perm)); } return result; } static SMB_ACL_T gpfsacl_get_posix_acl(const char *path, gpfs_aclType_t type, TALLOC_CTX *mem_ctx) { struct gpfs_acl *pacl; SMB_ACL_T result = NULL; pacl = vfs_gpfs_getacl(talloc_tos(), path, false, type); if (pacl == NULL) { DEBUG(10, ("vfs_gpfs_getacl failed for %s with %s\n", path, strerror(errno))); if (errno == 0) { errno = EINVAL; } goto done; } if (pacl->acl_version != GPFS_ACL_VERSION_POSIX) { DEBUG(10, ("Got acl version %d, expected %d\n", pacl->acl_version, GPFS_ACL_VERSION_POSIX)); errno = EINVAL; goto done; } DEBUG(10, ("len: %d, level: %d, version: %d, nace: %d\n", pacl->acl_len, pacl->acl_level, pacl->acl_version, pacl->acl_nace)); result = gpfs2smb_acl(pacl, mem_ctx); if (result != NULL) { errno = 0; } done: if (pacl != NULL) { talloc_free(pacl); } if (errno != 0) { TALLOC_FREE(result); } return result; } static SMB_ACL_T gpfsacl_sys_acl_get_fd(vfs_handle_struct *handle, files_struct *fsp, SMB_ACL_TYPE_T type, TALLOC_CTX *mem_ctx) { gpfs_aclType_t gpfs_type; struct gpfs_config_data *config; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return NULL); if (!config->acl) { return SMB_VFS_NEXT_SYS_ACL_GET_FD(handle, fsp, type, mem_ctx); } switch(type) { case SMB_ACL_TYPE_ACCESS: gpfs_type = GPFS_ACL_TYPE_ACCESS; break; case SMB_ACL_TYPE_DEFAULT: gpfs_type = GPFS_ACL_TYPE_DEFAULT; break; default: DEBUG(0, ("Got invalid type: %d\n", type)); smb_panic("exiting"); } return gpfsacl_get_posix_acl(fsp->fsp_name->base_name, gpfs_type, mem_ctx); } static int gpfsacl_sys_acl_blob_get_fd(vfs_handle_struct *handle, files_struct *fsp, TALLOC_CTX *mem_ctx, char **blob_description, DATA_BLOB *blob) { struct gpfs_config_data *config; struct gpfs_opaque_acl *acl = NULL; DATA_BLOB aclblob; int result; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return -1); if (!config->acl) { return SMB_VFS_NEXT_SYS_ACL_BLOB_GET_FD(handle, fsp, mem_ctx, blob_description, blob); } errno = 0; acl = (struct gpfs_opaque_acl *) vfs_gpfs_getacl(mem_ctx, fsp->fsp_name->base_name, true, GPFS_ACL_TYPE_NFS4); if (errno) { DEBUG(5, ("vfs_gpfs_getacl finished with errno %d: %s\n", errno, strerror(errno))); /* EINVAL means POSIX ACL, bail out on other cases */ if (errno != EINVAL) { return -1; } } if (acl != NULL) { /* * file has NFSv4 ACL * * we only need the actual ACL blob here * acl_version will always be NFS4 because we asked * for NFS4 * acl_type is only used for POSIX ACLs */ aclblob.data = (uint8_t*) acl->acl_var_data; aclblob.length = acl->acl_buffer_len; *blob_description = talloc_strdup(mem_ctx, "gpfs_nfs4_acl"); if (!*blob_description) { talloc_free(acl); errno = ENOMEM; return -1; } result = non_posix_sys_acl_blob_get_fd_helper(handle, fsp, aclblob, mem_ctx, blob); talloc_free(acl); return result; } /* fall back to POSIX ACL */ return posix_sys_acl_blob_get_fd(handle, fsp, mem_ctx, blob_description, blob); } static struct gpfs_acl *smb2gpfs_acl(const SMB_ACL_T pacl, SMB_ACL_TYPE_T type) { gpfs_aclLen_t len; struct gpfs_acl *result; int i; DEBUG(10, ("smb2gpfs_acl: Got ACL with %d entries\n", pacl->count)); len = offsetof(gpfs_acl_t, ace_v1) + (pacl->count) * sizeof(gpfs_ace_v1_t); result = (struct gpfs_acl *)SMB_MALLOC(len); if (result == NULL) { errno = ENOMEM; return result; } result->acl_len = len; result->acl_level = 0; result->acl_version = GPFS_ACL_VERSION_POSIX; result->acl_type = (type == SMB_ACL_TYPE_DEFAULT) ? GPFS_ACL_TYPE_DEFAULT : GPFS_ACL_TYPE_ACCESS; result->acl_nace = pacl->count; for (i=0; icount; i++) { const struct smb_acl_entry *ace = &pacl->acl[i]; struct gpfs_ace_v1 *g_ace = &result->ace_v1[i]; DEBUG(10, ("Converting type %d perm %x\n", (int)ace->a_type, (int)ace->a_perm)); g_ace->ace_perm = 0; switch(ace->a_type) { case SMB_ACL_USER: g_ace->ace_type = GPFS_ACL_USER; g_ace->ace_who = (gpfs_uid_t)ace->info.user.uid; break; case SMB_ACL_USER_OBJ: g_ace->ace_type = GPFS_ACL_USER_OBJ; g_ace->ace_perm |= ACL_PERM_CONTROL; g_ace->ace_who = 0; break; case SMB_ACL_GROUP: g_ace->ace_type = GPFS_ACL_GROUP; g_ace->ace_who = (gpfs_uid_t)ace->info.group.gid; break; case SMB_ACL_GROUP_OBJ: g_ace->ace_type = GPFS_ACL_GROUP_OBJ; g_ace->ace_who = 0; break; case SMB_ACL_MASK: g_ace->ace_type = GPFS_ACL_MASK; g_ace->ace_perm = 0x8f; g_ace->ace_who = 0; break; case SMB_ACL_OTHER: g_ace->ace_type = GPFS_ACL_OTHER; g_ace->ace_who = 0; break; default: DEBUG(10, ("Got invalid ace_type: %d\n", ace->a_type)); errno = EINVAL; SAFE_FREE(result); return NULL; } g_ace->ace_perm |= (ace->a_perm & SMB_ACL_READ) ? ACL_PERM_READ : 0; g_ace->ace_perm |= (ace->a_perm & SMB_ACL_WRITE) ? ACL_PERM_WRITE : 0; g_ace->ace_perm |= (ace->a_perm & SMB_ACL_EXECUTE) ? ACL_PERM_EXECUTE : 0; DEBUGADD(10, ("Converted to %d id %d perm %x\n", g_ace->ace_type, g_ace->ace_who, g_ace->ace_perm)); } return result; } static int gpfsacl_sys_acl_set_fd(vfs_handle_struct *handle, files_struct *fsp, SMB_ACL_TYPE_T type, SMB_ACL_T theacl) { struct gpfs_config_data *config; struct gpfs_acl *gpfs_acl = NULL; int result; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return -1); if (!config->acl) { return SMB_VFS_NEXT_SYS_ACL_SET_FD(handle, fsp, type, theacl); } gpfs_acl = smb2gpfs_acl(theacl, type); if (gpfs_acl == NULL) { return -1; } /* * This is no longer a handle based call. */ result = gpfswrap_putacl(fsp->fsp_name->base_name, GPFS_PUTACL_STRUCT|GPFS_ACL_SAMBA, gpfs_acl); SAFE_FREE(gpfs_acl); return result; } static int gpfsacl_sys_acl_delete_def_fd(vfs_handle_struct *handle, files_struct *fsp) { struct gpfs_config_data *config; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return -1); if (!config->acl) { return SMB_VFS_NEXT_SYS_ACL_DELETE_DEF_FD(handle, fsp); } errno = ENOTSUP; return -1; } /* * Assumed: mode bits are shiftable and standard * Output: the new aceMask field for an smb nfs4 ace */ static uint32_t gpfsacl_mask_filter(uint32_t aceType, uint32_t aceMask, uint32_t rwx) { const uint32_t posix_nfs4map[3] = { SMB_ACE4_EXECUTE, /* execute */ SMB_ACE4_WRITE_DATA | SMB_ACE4_APPEND_DATA, /* write; GPFS specific */ SMB_ACE4_READ_DATA /* read */ }; int i; uint32_t posix_mask = 0x01; uint32_t posix_bit; uint32_t nfs4_bits; for(i=0; i<3; i++) { nfs4_bits = posix_nfs4map[i]; posix_bit = rwx & posix_mask; if (aceType==SMB_ACE4_ACCESS_ALLOWED_ACE_TYPE) { if (posix_bit) aceMask |= nfs4_bits; else aceMask &= ~nfs4_bits; } else { /* add deny bits when suitable */ if (!posix_bit) aceMask |= nfs4_bits; else aceMask &= ~nfs4_bits; } /* other ace types are unexpected */ posix_mask <<= 1; } return aceMask; } static int gpfsacl_emu_chmod(vfs_handle_struct *handle, const struct smb_filename *fname, mode_t mode) { char *path = fname->base_name; struct SMB4ACL_T *pacl = NULL; int result; bool haveAllowEntry[SMB_ACE4_WHO_EVERYONE + 1] = {False, False, False, False}; int i; files_struct fake_fsp = { 0 }; /* TODO: rationalize parametrization */ struct SMB4ACE_T *smbace; TALLOC_CTX *frame = talloc_stackframe(); DEBUG(10, ("gpfsacl_emu_chmod invoked for %s mode %o\n", path, mode)); result = gpfs_get_nfs4_acl(frame, path, &pacl); if (result) { TALLOC_FREE(frame); return result; } if (mode & ~(S_IRWXU | S_IRWXG | S_IRWXO)) { DEBUG(2, ("WARNING: cutting extra mode bits %o on %s\n", mode, path)); } for (smbace=smb_first_ace4(pacl); smbace!=NULL; smbace = smb_next_ace4(smbace)) { SMB_ACE4PROP_T *ace = smb_get_ace4(smbace); uint32_t specid = ace->who.special_id; if (ace->flags&SMB_ACE4_ID_SPECIAL && ace->aceType<=SMB_ACE4_ACCESS_DENIED_ACE_TYPE && specid <= SMB_ACE4_WHO_EVERYONE) { uint32_t newMask; if (ace->aceType==SMB_ACE4_ACCESS_ALLOWED_ACE_TYPE) haveAllowEntry[specid] = True; /* mode >> 6 for @owner, mode >> 3 for @group, * mode >> 0 for @everyone */ newMask = gpfsacl_mask_filter(ace->aceType, ace->aceMask, mode >> ((SMB_ACE4_WHO_EVERYONE - specid) * 3)); if (ace->aceMask!=newMask) { DEBUG(10, ("ace changed for %s (%o -> %o) id=%d\n", path, ace->aceMask, newMask, specid)); } ace->aceMask = newMask; } } /* make sure we have at least ALLOW entries * for all the 3 special ids (@EVERYONE, @OWNER, @GROUP) * - if necessary */ for(i = SMB_ACE4_WHO_OWNER; i<=SMB_ACE4_WHO_EVERYONE; i++) { SMB_ACE4PROP_T ace = { 0 }; if (haveAllowEntry[i]==True) continue; ace.aceType = SMB_ACE4_ACCESS_ALLOWED_ACE_TYPE; ace.flags |= SMB_ACE4_ID_SPECIAL; ace.who.special_id = i; if (i==SMB_ACE4_WHO_GROUP) /* not sure it's necessary... */ ace.aceFlags |= SMB_ACE4_IDENTIFIER_GROUP; ace.aceMask = gpfsacl_mask_filter(ace.aceType, ace.aceMask, mode >> ((SMB_ACE4_WHO_EVERYONE - i) * 3)); /* don't add unnecessary aces */ if (!ace.aceMask) continue; /* we add it to the END - as windows expects allow aces */ smb_add_ace4(pacl, &ace); DEBUG(10, ("Added ALLOW ace for %s, mode=%o, id=%d, aceMask=%x\n", path, mode, i, ace.aceMask)); } /* don't add complementary DENY ACEs here */ fake_fsp.fsp_name = synthetic_smb_fname(frame, path, NULL, NULL, fname->twrp, 0); if (fake_fsp.fsp_name == NULL) { errno = ENOMEM; TALLOC_FREE(frame); return -1; } /* put the acl */ if (gpfsacl_process_smbacl(handle, &fake_fsp, pacl) == False) { TALLOC_FREE(frame); return -1; } TALLOC_FREE(frame); return 0; /* ok for [f]chmod */ } static int vfs_gpfs_fchmod(vfs_handle_struct *handle, files_struct *fsp, mode_t mode) { SMB_STRUCT_STAT st; int rc; if (SMB_VFS_NEXT_FSTAT(handle, fsp, &st) != 0) { return -1; } /* avoid chmod() if possible, to preserve acls */ if ((st.st_ex_mode & ~S_IFMT) == mode) { return 0; } rc = gpfsacl_emu_chmod(handle, fsp->fsp_name, mode); if (rc == 1) return SMB_VFS_NEXT_FCHMOD(handle, fsp, mode); return rc; } static uint32_t vfs_gpfs_winattrs_to_dosmode(unsigned int winattrs) { uint32_t dosmode = 0; if (winattrs & GPFS_WINATTR_ARCHIVE){ dosmode |= FILE_ATTRIBUTE_ARCHIVE; } if (winattrs & GPFS_WINATTR_HIDDEN){ dosmode |= FILE_ATTRIBUTE_HIDDEN; } if (winattrs & GPFS_WINATTR_SYSTEM){ dosmode |= FILE_ATTRIBUTE_SYSTEM; } if (winattrs & GPFS_WINATTR_READONLY){ dosmode |= FILE_ATTRIBUTE_READONLY; } if (winattrs & GPFS_WINATTR_SPARSE_FILE) { dosmode |= FILE_ATTRIBUTE_SPARSE; } if (winattrs & GPFS_WINATTR_OFFLINE) { dosmode |= FILE_ATTRIBUTE_OFFLINE; } return dosmode; } static unsigned int vfs_gpfs_dosmode_to_winattrs(uint32_t dosmode) { unsigned int winattrs = 0; if (dosmode & FILE_ATTRIBUTE_ARCHIVE){ winattrs |= GPFS_WINATTR_ARCHIVE; } if (dosmode & FILE_ATTRIBUTE_HIDDEN){ winattrs |= GPFS_WINATTR_HIDDEN; } if (dosmode & FILE_ATTRIBUTE_SYSTEM){ winattrs |= GPFS_WINATTR_SYSTEM; } if (dosmode & FILE_ATTRIBUTE_READONLY){ winattrs |= GPFS_WINATTR_READONLY; } if (dosmode & FILE_ATTRIBUTE_SPARSE) { winattrs |= GPFS_WINATTR_SPARSE_FILE; } if (dosmode & FILE_ATTRIBUTE_OFFLINE) { winattrs |= GPFS_WINATTR_OFFLINE; } return winattrs; } static NTSTATUS vfs_gpfs_get_file_id(struct gpfs_iattr64 *iattr, uint64_t *fileid) { uint8_t input[sizeof(gpfs_ino64_t) + sizeof(gpfs_gen64_t) + sizeof(gpfs_snapid64_t)]; uint8_t digest[gnutls_hash_get_len(GNUTLS_DIG_SHA1)]; int rc; DBG_DEBUG("ia_inode 0x%llx, ia_gen 0x%llx, ia_modsnapid 0x%llx\n", iattr->ia_inode, iattr->ia_gen, iattr->ia_modsnapid); SBVAL(input, 0, iattr->ia_inode); SBVAL(input, sizeof(gpfs_ino64_t), iattr->ia_gen); SBVAL(input, sizeof(gpfs_ino64_t) + sizeof(gpfs_gen64_t), iattr->ia_modsnapid); GNUTLS_FIPS140_SET_LAX_MODE(); rc = gnutls_hash_fast(GNUTLS_DIG_SHA1, input, sizeof(input), &digest); GNUTLS_FIPS140_SET_STRICT_MODE(); if (rc != 0) { return gnutls_error_to_ntstatus(rc, NT_STATUS_HASH_NOT_SUPPORTED); } memcpy(fileid, &digest, sizeof(*fileid)); DBG_DEBUG("file_id 0x%" PRIx64 "\n", *fileid); return NT_STATUS_OK; } static struct timespec gpfs_timestruc64_to_timespec(struct gpfs_timestruc64 g) { return (struct timespec) { .tv_sec = g.tv_sec, .tv_nsec = g.tv_nsec }; } static NTSTATUS vfs_gpfs_fget_dos_attributes(struct vfs_handle_struct *handle, struct files_struct *fsp, uint32_t *dosmode) { struct gpfs_config_data *config; int fd = fsp_get_pathref_fd(fsp); char buf[PATH_MAX]; const char *p = NULL; struct gpfs_iattr64 iattr = { }; unsigned int litemask; struct timespec ts; uint64_t file_id; NTSTATUS status; int ret; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return NT_STATUS_INTERNAL_ERROR); if (!config->winattr) { return SMB_VFS_NEXT_FGET_DOS_ATTRIBUTES(handle, fsp, dosmode); } if (fsp->fsp_flags.is_pathref && !config->pathref_ok.gpfs_fstat_x) { if (fsp->fsp_flags.have_proc_fds) { p = sys_proc_fd_path(fd, buf, sizeof(buf)); if (p == NULL) { return NT_STATUS_NO_MEMORY; } } else { p = fsp->fsp_name->base_name; } } if (p != NULL) { ret = gpfswrap_stat_x(p, &litemask, &iattr, sizeof(iattr)); } else { ret = gpfswrap_fstat_x(fd, &litemask, &iattr, sizeof(iattr)); } if (ret == -1 && errno == ENOSYS) { return SMB_VFS_NEXT_FGET_DOS_ATTRIBUTES(handle, fsp, dosmode); } if (ret == -1 && errno == EACCES) { int saved_errno = 0; /* * According to MS-FSA 2.1.5.1.2.1 "Algorithm to Check Access to * an Existing File" FILE_LIST_DIRECTORY on a directory implies * FILE_READ_ATTRIBUTES for directory entries. Being able to * open a file implies FILE_LIST_DIRECTORY. */ set_effective_capability(DAC_OVERRIDE_CAPABILITY); if (p != NULL) { ret = gpfswrap_stat_x(p, &litemask, &iattr, sizeof(iattr)); } else { ret = gpfswrap_fstat_x(fd, &litemask, &iattr, sizeof(iattr)); } if (ret == -1) { saved_errno = errno; } drop_effective_capability(DAC_OVERRIDE_CAPABILITY); if (saved_errno != 0) { errno = saved_errno; } } if (ret == -1) { DBG_WARNING("Getting winattrs failed for %s: %s\n", fsp->fsp_name->base_name, strerror(errno)); return map_nt_error_from_unix(errno); } ZERO_STRUCT(file_id); status = vfs_gpfs_get_file_id(&iattr, &file_id); if (!NT_STATUS_IS_OK(status)) { return status; } ts = gpfs_timestruc64_to_timespec(iattr.ia_createtime); *dosmode |= vfs_gpfs_winattrs_to_dosmode(iattr.ia_winflags); update_stat_ex_create_time(&fsp->fsp_name->st, ts); update_stat_ex_file_id(&fsp->fsp_name->st, file_id); return NT_STATUS_OK; } static NTSTATUS vfs_gpfs_fset_dos_attributes(struct vfs_handle_struct *handle, struct files_struct *fsp, uint32_t dosmode) { struct gpfs_config_data *config; struct gpfs_winattr attrs = { }; int ret; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return NT_STATUS_INTERNAL_ERROR); if (!config->winattr) { return SMB_VFS_NEXT_FSET_DOS_ATTRIBUTES(handle, fsp, dosmode); } attrs.winAttrs = vfs_gpfs_dosmode_to_winattrs(dosmode); ret = gpfswrap_set_winattrs(fsp_get_io_fd(fsp), GPFS_WINATTR_SET_ATTRS, &attrs); if (ret == -1 && errno == ENOSYS) { return SMB_VFS_NEXT_FSET_DOS_ATTRIBUTES(handle, fsp, dosmode); } if (ret == -1) { DBG_WARNING("Setting winattrs failed for %s: %s\n", fsp->fsp_name->base_name, strerror(errno)); return map_nt_error_from_unix(errno); } return NT_STATUS_OK; } static int stat_with_capability(struct vfs_handle_struct *handle, struct smb_filename *smb_fname, int flag) { int fd = -1; NTSTATUS status; struct smb_filename *dir_name = NULL; struct smb_filename *rel_name = NULL; struct stat st; int ret = -1; status = SMB_VFS_PARENT_PATHNAME(handle->conn, talloc_tos(), smb_fname, &dir_name, &rel_name); if (!NT_STATUS_IS_OK(status)) { errno = map_errno_from_nt_status(status); return -1; } fd = open(dir_name->base_name, O_RDONLY, 0); if (fd == -1) { TALLOC_FREE(dir_name); return -1; } set_effective_capability(DAC_OVERRIDE_CAPABILITY); ret = fstatat(fd, rel_name->base_name, &st, flag); drop_effective_capability(DAC_OVERRIDE_CAPABILITY); TALLOC_FREE(dir_name); close(fd); if (ret == 0) { init_stat_ex_from_stat( &smb_fname->st, &st, lp_fake_directory_create_times(SNUM(handle->conn))); } return ret; } static int vfs_gpfs_stat(struct vfs_handle_struct *handle, struct smb_filename *smb_fname) { int ret; ret = SMB_VFS_NEXT_STAT(handle, smb_fname); if (ret == -1 && errno == EACCES) { DEBUG(10, ("Trying stat with capability for %s\n", smb_fname->base_name)); ret = stat_with_capability(handle, smb_fname, 0); } return ret; } static int vfs_gpfs_lstat(struct vfs_handle_struct *handle, struct smb_filename *smb_fname) { int ret; ret = SMB_VFS_NEXT_LSTAT(handle, smb_fname); if (ret == -1 && errno == EACCES) { DEBUG(10, ("Trying lstat with capability for %s\n", smb_fname->base_name)); ret = stat_with_capability(handle, smb_fname, AT_SYMLINK_NOFOLLOW); } return ret; } static void timespec_to_gpfs_time(struct timespec ts, gpfs_timestruc_t *gt, int idx, int *flags) { if (!is_omit_timespec(&ts)) { *flags |= 1 << idx; gt[idx].tv_sec = ts.tv_sec; gt[idx].tv_nsec = ts.tv_nsec; DEBUG(10, ("Setting GPFS time %d, flags 0x%x\n", idx, *flags)); } } static int smbd_gpfs_set_times(int fd, char *path, struct smb_file_time *ft) { gpfs_timestruc_t gpfs_times[4]; int flags = 0; int rc; ZERO_ARRAY(gpfs_times); timespec_to_gpfs_time(ft->atime, gpfs_times, 0, &flags); timespec_to_gpfs_time(ft->mtime, gpfs_times, 1, &flags); /* No good mapping from LastChangeTime to ctime, not storing */ timespec_to_gpfs_time(ft->create_time, gpfs_times, 3, &flags); if (!flags) { DBG_DEBUG("nothing to do, return to avoid EINVAL\n"); return 0; } rc = gpfswrap_set_times(fd, flags, gpfs_times); if (rc != 0 && errno != ENOSYS) { DBG_WARNING("gpfs_set_times() returned with error %s for %s\n", strerror(errno), path); } return rc; } static int vfs_gpfs_fntimes(struct vfs_handle_struct *handle, files_struct *fsp, struct smb_file_time *ft) { struct gpfs_winattr attrs; int ret; struct gpfs_config_data *config; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return -1); /* Try to use gpfs_set_times if it is enabled and available */ if (config->settimes) { ret = smbd_gpfs_set_times(fsp_get_io_fd(fsp), fsp->fsp_name->base_name, ft); if (ret == 0 || (ret == -1 && errno != ENOSYS)) { return ret; } } DBG_DEBUG("gpfs_set_times() not available or disabled, " "use ntimes and winattr\n"); ret = SMB_VFS_NEXT_FNTIMES(handle, fsp, ft); if (ret == -1) { /* don't complain if access was denied */ if (errno != EPERM && errno != EACCES) { DBG_WARNING("SMB_VFS_NEXT_FNTIMES failed: %s", strerror(errno)); } return -1; } if (is_omit_timespec(&ft->create_time)) { DBG_DEBUG("Create Time is NULL\n"); return 0; } if (!config->winattr) { return 0; } attrs.winAttrs = 0; attrs.creationTime.tv_sec = ft->create_time.tv_sec; attrs.creationTime.tv_nsec = ft->create_time.tv_nsec; ret = gpfswrap_set_winattrs(fsp_get_io_fd(fsp), GPFS_WINATTR_SET_CREATION_TIME, &attrs); if (ret == -1 && errno != ENOSYS) { DBG_WARNING("Set GPFS ntimes failed %d\n", ret); return -1; } return 0; } static int vfs_gpfs_fallocate(struct vfs_handle_struct *handle, struct files_struct *fsp, uint32_t mode, off_t offset, off_t len) { if (mode == (VFS_FALLOCATE_FL_PUNCH_HOLE|VFS_FALLOCATE_FL_KEEP_SIZE) && !fsp->fsp_flags.is_sparse && lp_strict_allocate(SNUM(fsp->conn))) { /* * This is from a ZERO_DATA request on a non-sparse * file. GPFS does not support FL_KEEP_SIZE and thus * cannot fill the whole again in the subsequent * fallocate(FL_KEEP_SIZE). Deny this FL_PUNCH_HOLE * call to not end up with a hole in a non-sparse * file. */ errno = ENOTSUP; return -1; } return SMB_VFS_NEXT_FALLOCATE(handle, fsp, mode, offset, len); } static int vfs_gpfs_ftruncate(vfs_handle_struct *handle, files_struct *fsp, off_t len) { int result; struct gpfs_config_data *config; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return -1); if (!config->ftruncate) { return SMB_VFS_NEXT_FTRUNCATE(handle, fsp, len); } result = gpfswrap_ftruncate(fsp_get_io_fd(fsp), len); if ((result == -1) && (errno == ENOSYS)) { return SMB_VFS_NEXT_FTRUNCATE(handle, fsp, len); } return result; } static bool vfs_gpfs_is_offline(struct vfs_handle_struct *handle, const struct smb_filename *fname, SMB_STRUCT_STAT *sbuf) { struct gpfs_winattr attrs; struct gpfs_config_data *config; int ret; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return false); if (!config->winattr) { return false; } ret = gpfswrap_get_winattrs_path(fname->base_name, &attrs); if (ret == -1) { return false; } if ((attrs.winAttrs & GPFS_WINATTR_OFFLINE) != 0) { DBG_DEBUG("%s is offline\n", fname->base_name); return true; } DBG_DEBUG("%s is online\n", fname->base_name); return false; } static bool vfs_gpfs_fsp_is_offline(struct vfs_handle_struct *handle, struct files_struct *fsp) { struct gpfs_fsp_extension *ext; ext = VFS_FETCH_FSP_EXTENSION(handle, fsp); if (ext == NULL) { /* * Something bad happened, always ask. */ return vfs_gpfs_is_offline(handle, fsp->fsp_name, &fsp->fsp_name->st); } if (ext->offline) { /* * As long as it's offline, ask. */ ext->offline = vfs_gpfs_is_offline(handle, fsp->fsp_name, &fsp->fsp_name->st); } return ext->offline; } static bool vfs_gpfs_aio_force(struct vfs_handle_struct *handle, struct files_struct *fsp) { return vfs_gpfs_fsp_is_offline(handle, fsp); } static ssize_t vfs_gpfs_sendfile(vfs_handle_struct *handle, int tofd, files_struct *fsp, const DATA_BLOB *hdr, off_t offset, size_t n) { if (vfs_gpfs_fsp_is_offline(handle, fsp)) { errno = ENOSYS; return -1; } return SMB_VFS_NEXT_SENDFILE(handle, tofd, fsp, hdr, offset, n); } #ifdef O_PATH static int vfs_gpfs_check_pathref_fstat_x(struct gpfs_config_data *config, struct connection_struct *conn) { struct gpfs_iattr64 iattr = {0}; unsigned int litemask; int saved_errno; int fd; int ret; fd = open(conn->connectpath, O_PATH); if (fd == -1) { DBG_ERR("openat() of share with O_PATH failed: %s\n", strerror(errno)); return -1; } ret = gpfswrap_fstat_x(fd, &litemask, &iattr, sizeof(iattr)); if (ret == 0) { close(fd); config->pathref_ok.gpfs_fstat_x = true; return 0; } saved_errno = errno; ret = close(fd); if (ret != 0) { DBG_ERR("close failed: %s\n", strerror(errno)); return -1; } if (saved_errno != EBADF) { DBG_ERR("gpfswrap_fstat_x() of O_PATH handle failed: %s\n", strerror(saved_errno)); return -1; } return 0; } #endif static int vfs_gpfs_check_pathref(struct gpfs_config_data *config, struct connection_struct *conn) { #ifndef O_PATH /* * This code path leaves all struct gpfs_config_data.pathref_ok members * initialized to false. */ return 0; #else int ret; ret = vfs_gpfs_check_pathref_fstat_x(config, conn); if (ret != 0) { return -1; } return 0; #endif } static int vfs_gpfs_connect(struct vfs_handle_struct *handle, const char *service, const char *user) { struct gpfs_config_data *config; int ret; bool check_fstype; ret = SMB_VFS_NEXT_CONNECT(handle, service, user); if (ret < 0) { return ret; } if (IS_IPC(handle->conn)) { return 0; } gpfswrap_lib_init(0); config = talloc_zero(handle->conn, struct gpfs_config_data); if (!config) { DEBUG(0, ("talloc_zero() failed\n")); errno = ENOMEM; return -1; } check_fstype = lp_parm_bool(SNUM(handle->conn), "gpfs", "check_fstype", true); if (check_fstype) { const char *connectpath = handle->conn->connectpath; struct statfs buf = { 0 }; ret = statfs(connectpath, &buf); if (ret != 0) { DBG_ERR("statfs failed for share %s at path %s: %s\n", service, connectpath, strerror(errno)); TALLOC_FREE(config); return ret; } if (buf.f_type != GPFS_SUPER_MAGIC) { DBG_ERR("SMB share %s, path %s not in GPFS file system." " statfs magic: 0x%jx\n", service, connectpath, (uintmax_t)buf.f_type); errno = EINVAL; TALLOC_FREE(config); return -1; } } ret = smbacl4_get_vfs_params(handle->conn, &config->nfs4_params); if (ret < 0) { TALLOC_FREE(config); return ret; } config->sharemodes = lp_parm_bool(SNUM(handle->conn), "gpfs", "sharemodes", true); config->leases = lp_parm_bool(SNUM(handle->conn), "gpfs", "leases", true); config->hsm = lp_parm_bool(SNUM(handle->conn), "gpfs", "hsm", false); config->syncio = lp_parm_bool(SNUM(handle->conn), "gpfs", "syncio", false); config->winattr = lp_parm_bool(SNUM(handle->conn), "gpfs", "winattr", false); config->ftruncate = lp_parm_bool(SNUM(handle->conn), "gpfs", "ftruncate", true); config->getrealfilename = lp_parm_bool(SNUM(handle->conn), "gpfs", "getrealfilename", true); config->dfreequota = lp_parm_bool(SNUM(handle->conn), "gpfs", "dfreequota", false); config->acl = lp_parm_bool(SNUM(handle->conn), "gpfs", "acl", true); config->settimes = lp_parm_bool(SNUM(handle->conn), "gpfs", "settimes", true); config->recalls = lp_parm_bool(SNUM(handle->conn), "gpfs", "recalls", true); ret = vfs_gpfs_check_pathref(config, handle->conn); if (ret != 0) { DBG_ERR("vfs_gpfs_check_pathref() on [%s] failed\n", handle->conn->connectpath); TALLOC_FREE(config); return -1; } SMB_VFS_HANDLE_SET_DATA(handle, config, NULL, struct gpfs_config_data, return -1); if (config->leases) { /* * GPFS lease code is based on kernel oplock code * so make sure it is turned on */ if (!lp_kernel_oplocks(SNUM(handle->conn))) { DEBUG(5, ("Enabling kernel oplocks for " "gpfs:leases to work\n")); lp_do_parameter(SNUM(handle->conn), "kernel oplocks", "true"); } /* * as the kernel does not properly support Level II oplocks * and GPFS leases code is based on kernel infrastructure, we * need to turn off Level II oplocks if gpfs:leases is enabled */ if (lp_level2_oplocks(SNUM(handle->conn))) { DEBUG(5, ("gpfs:leases are enabled, disabling " "Level II oplocks\n")); lp_do_parameter(SNUM(handle->conn), "level2 oplocks", "false"); } } /* * Unless we have an async implementation of get_dos_attributes turn * this off. */ lp_do_parameter(SNUM(handle->conn), "smbd async dosmode", "false"); return 0; } static int get_gpfs_quota(const char *pathname, int type, int id, struct gpfs_quotaInfo *qi) { int ret; ret = gpfswrap_quotactl(pathname, GPFS_QCMD(Q_GETQUOTA, type), id, qi); if (ret) { if (errno == GPFS_E_NO_QUOTA_INST) { DEBUG(10, ("Quotas disabled on GPFS filesystem.\n")); } else if (errno != ENOSYS) { DEBUG(0, ("Get quota failed, type %d, id, %d, " "errno %d.\n", type, id, errno)); } return ret; } DEBUG(10, ("quota type %d, id %d, blk u:%lld h:%lld s:%lld gt:%u\n", type, id, qi->blockUsage, qi->blockHardLimit, qi->blockSoftLimit, qi->blockGraceTime)); return ret; } static void vfs_gpfs_disk_free_quota(struct gpfs_quotaInfo qi, time_t cur_time, uint64_t *dfree, uint64_t *dsize) { uint64_t usage, limit; /* * The quota reporting is done in units of 1024 byte blocks, but * sys_fsusage uses units of 512 byte blocks, adjust the block number * accordingly. Also filter possibly negative usage counts from gpfs. */ usage = qi.blockUsage < 0 ? 0 : (uint64_t)qi.blockUsage * 2; limit = (uint64_t)qi.blockHardLimit * 2; /* * When the grace time for the exceeded soft block quota has been * exceeded, the soft block quota becomes an additional hard limit. */ if (qi.blockSoftLimit && qi.blockGraceTime && cur_time > qi.blockGraceTime) { /* report disk as full */ *dfree = 0; *dsize = MIN(*dsize, usage); } if (!qi.blockHardLimit) return; if (usage >= limit) { /* report disk as full */ *dfree = 0; *dsize = MIN(*dsize, usage); } else { /* limit has not been reached, determine "free space" */ *dfree = MIN(*dfree, limit - usage); *dsize = MIN(*dsize, limit); } } static uint64_t vfs_gpfs_disk_free(vfs_handle_struct *handle, const struct smb_filename *smb_fname, uint64_t *bsize, uint64_t *dfree, uint64_t *dsize) { struct security_unix_token *utok; struct gpfs_quotaInfo qi_user = { 0 }, qi_group = { 0 }; struct gpfs_config_data *config; int err; time_t cur_time; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return (uint64_t)-1); if (!config->dfreequota) { return SMB_VFS_NEXT_DISK_FREE(handle, smb_fname, bsize, dfree, dsize); } err = sys_fsusage(smb_fname->base_name, dfree, dsize); if (err) { DEBUG (0, ("Could not get fs usage, errno %d\n", errno)); return SMB_VFS_NEXT_DISK_FREE(handle, smb_fname, bsize, dfree, dsize); } /* sys_fsusage returns units of 512 bytes */ *bsize = 512; DEBUG(10, ("fs dfree %llu, dsize %llu\n", (unsigned long long)*dfree, (unsigned long long)*dsize)); utok = handle->conn->session_info->unix_token; err = get_gpfs_quota(smb_fname->base_name, GPFS_USRQUOTA, utok->uid, &qi_user); if (err) { return SMB_VFS_NEXT_DISK_FREE(handle, smb_fname, bsize, dfree, dsize); } /* * If new files created under this folder get this folder's * GID, then available space is governed by the quota of the * folder's GID, not the primary group of the creating user. */ if (VALID_STAT(smb_fname->st) && S_ISDIR(smb_fname->st.st_ex_mode) && smb_fname->st.st_ex_mode & S_ISGID) { become_root(); err = get_gpfs_quota(smb_fname->base_name, GPFS_GRPQUOTA, smb_fname->st.st_ex_gid, &qi_group); unbecome_root(); } else { err = get_gpfs_quota(smb_fname->base_name, GPFS_GRPQUOTA, utok->gid, &qi_group); } if (err) { return SMB_VFS_NEXT_DISK_FREE(handle, smb_fname, bsize, dfree, dsize); } cur_time = time(NULL); /* Adjust free space and size according to quota limits. */ vfs_gpfs_disk_free_quota(qi_user, cur_time, dfree, dsize); vfs_gpfs_disk_free_quota(qi_group, cur_time, dfree, dsize); return *dfree / 2; } static int vfs_gpfs_get_quota(vfs_handle_struct *handle, const struct smb_filename *smb_fname, enum SMB_QUOTA_TYPE qtype, unid_t id, SMB_DISK_QUOTA *dq) { switch(qtype) { /* * User/group quota are being used for disk-free * determination, which in this module is done directly * by the disk-free function. It's important that this * module does not return wrong quota values by mistake, * which would modify the correct values set by disk-free. * User/group quota are also being used for processing * NT_TRANSACT_GET_USER_QUOTA in smb1 protocol, which is * currently not supported by this module. */ case SMB_USER_QUOTA_TYPE: case SMB_GROUP_QUOTA_TYPE: errno = ENOSYS; return -1; default: return SMB_VFS_NEXT_GET_QUOTA(handle, smb_fname, qtype, id, dq); } } static uint32_t vfs_gpfs_capabilities(struct vfs_handle_struct *handle, enum timestamp_set_resolution *p_ts_res) { struct gpfs_config_data *config; uint32_t next; next = SMB_VFS_NEXT_FS_CAPABILITIES(handle, p_ts_res); SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return next); if (config->hsm) { next |= FILE_SUPPORTS_REMOTE_STORAGE; } return next; } static int vfs_gpfs_openat(struct vfs_handle_struct *handle, const struct files_struct *dirfsp, const struct smb_filename *smb_fname, files_struct *fsp, int flags, mode_t mode) { struct gpfs_config_data *config = NULL; struct gpfs_fsp_extension *ext = NULL; int ret; SMB_VFS_HANDLE_GET_DATA(handle, config, struct gpfs_config_data, return -1); if (config->hsm && !config->recalls && vfs_gpfs_fsp_is_offline(handle, fsp)) { DBG_DEBUG("Refusing access to offline file %s\n", fsp_str_dbg(fsp)); errno = EACCES; return -1; } if (config->syncio) { flags |= O_SYNC; } ext = VFS_ADD_FSP_EXTENSION(handle, fsp, struct gpfs_fsp_extension, NULL); if (ext == NULL) { errno = ENOMEM; return -1; } /* * Assume the file is offline until gpfs tells us it's online. */ *ext = (struct gpfs_fsp_extension) { .offline = true }; ret = SMB_VFS_NEXT_OPENAT(handle, dirfsp, smb_fname, fsp, flags, mode); if (ret == -1) { VFS_REMOVE_FSP_EXTENSION(handle, fsp); } return ret; } static ssize_t vfs_gpfs_pread(vfs_handle_struct *handle, files_struct *fsp, void *data, size_t n, off_t offset) { ssize_t ret; bool was_offline; was_offline = vfs_gpfs_fsp_is_offline(handle, fsp); ret = SMB_VFS_NEXT_PREAD(handle, fsp, data, n, offset); if ((ret != -1) && was_offline) { notify_fname(handle->conn, NOTIFY_ACTION_MODIFIED, FILE_NOTIFY_CHANGE_ATTRIBUTES, fsp->fsp_name->base_name); } return ret; } struct vfs_gpfs_pread_state { struct files_struct *fsp; ssize_t ret; bool was_offline; struct vfs_aio_state vfs_aio_state; }; static void vfs_gpfs_pread_done(struct tevent_req *subreq); static struct tevent_req *vfs_gpfs_pread_send(struct vfs_handle_struct *handle, TALLOC_CTX *mem_ctx, struct tevent_context *ev, struct files_struct *fsp, void *data, size_t n, off_t offset) { struct tevent_req *req, *subreq; struct vfs_gpfs_pread_state *state; req = tevent_req_create(mem_ctx, &state, struct vfs_gpfs_pread_state); if (req == NULL) { return NULL; } state->was_offline = vfs_gpfs_fsp_is_offline(handle, fsp); state->fsp = fsp; subreq = SMB_VFS_NEXT_PREAD_SEND(state, ev, handle, fsp, data, n, offset); if (tevent_req_nomem(subreq, req)) { return tevent_req_post(req, ev); } tevent_req_set_callback(subreq, vfs_gpfs_pread_done, req); return req; } static void vfs_gpfs_pread_done(struct tevent_req *subreq) { struct tevent_req *req = tevent_req_callback_data( subreq, struct tevent_req); struct vfs_gpfs_pread_state *state = tevent_req_data( req, struct vfs_gpfs_pread_state); state->ret = SMB_VFS_PREAD_RECV(subreq, &state->vfs_aio_state); TALLOC_FREE(subreq); tevent_req_done(req); } static ssize_t vfs_gpfs_pread_recv(struct tevent_req *req, struct vfs_aio_state *vfs_aio_state) { struct vfs_gpfs_pread_state *state = tevent_req_data( req, struct vfs_gpfs_pread_state); struct files_struct *fsp = state->fsp; if (tevent_req_is_unix_error(req, &vfs_aio_state->error)) { return -1; } *vfs_aio_state = state->vfs_aio_state; if ((state->ret != -1) && state->was_offline) { DEBUG(10, ("sending notify\n")); notify_fname(fsp->conn, NOTIFY_ACTION_MODIFIED, FILE_NOTIFY_CHANGE_ATTRIBUTES, fsp->fsp_name->base_name); } return state->ret; } static ssize_t vfs_gpfs_pwrite(vfs_handle_struct *handle, files_struct *fsp, const void *data, size_t n, off_t offset) { ssize_t ret; bool was_offline; was_offline = vfs_gpfs_fsp_is_offline(handle, fsp); ret = SMB_VFS_NEXT_PWRITE(handle, fsp, data, n, offset); if ((ret != -1) && was_offline) { notify_fname(handle->conn, NOTIFY_ACTION_MODIFIED, FILE_NOTIFY_CHANGE_ATTRIBUTES, fsp->fsp_name->base_name); } return ret; } struct vfs_gpfs_pwrite_state { struct files_struct *fsp; ssize_t ret; bool was_offline; struct vfs_aio_state vfs_aio_state; }; static void vfs_gpfs_pwrite_done(struct tevent_req *subreq); static struct tevent_req *vfs_gpfs_pwrite_send( struct vfs_handle_struct *handle, TALLOC_CTX *mem_ctx, struct tevent_context *ev, struct files_struct *fsp, const void *data, size_t n, off_t offset) { struct tevent_req *req, *subreq; struct vfs_gpfs_pwrite_state *state; req = tevent_req_create(mem_ctx, &state, struct vfs_gpfs_pwrite_state); if (req == NULL) { return NULL; } state->was_offline = vfs_gpfs_fsp_is_offline(handle, fsp); state->fsp = fsp; subreq = SMB_VFS_NEXT_PWRITE_SEND(state, ev, handle, fsp, data, n, offset); if (tevent_req_nomem(subreq, req)) { return tevent_req_post(req, ev); } tevent_req_set_callback(subreq, vfs_gpfs_pwrite_done, req); return req; } static void vfs_gpfs_pwrite_done(struct tevent_req *subreq) { struct tevent_req *req = tevent_req_callback_data( subreq, struct tevent_req); struct vfs_gpfs_pwrite_state *state = tevent_req_data( req, struct vfs_gpfs_pwrite_state); state->ret = SMB_VFS_PWRITE_RECV(subreq, &state->vfs_aio_state); TALLOC_FREE(subreq); tevent_req_done(req); } static ssize_t vfs_gpfs_pwrite_recv(struct tevent_req *req, struct vfs_aio_state *vfs_aio_state) { struct vfs_gpfs_pwrite_state *state = tevent_req_data( req, struct vfs_gpfs_pwrite_state); struct files_struct *fsp = state->fsp; if (tevent_req_is_unix_error(req, &vfs_aio_state->error)) { return -1; } *vfs_aio_state = state->vfs_aio_state; if ((state->ret != -1) && state->was_offline) { DEBUG(10, ("sending notify\n")); notify_fname(fsp->conn, NOTIFY_ACTION_MODIFIED, FILE_NOTIFY_CHANGE_ATTRIBUTES, fsp->fsp_name->base_name); } return state->ret; } static struct vfs_fn_pointers vfs_gpfs_fns = { .connect_fn = vfs_gpfs_connect, .disk_free_fn = vfs_gpfs_disk_free, .get_quota_fn = vfs_gpfs_get_quota, .fs_capabilities_fn = vfs_gpfs_capabilities, .kernel_flock_fn = vfs_gpfs_kernel_flock, .linux_setlease_fn = vfs_gpfs_setlease, .get_real_filename_fn = vfs_gpfs_get_real_filename, .get_dos_attributes_send_fn = vfs_not_implemented_get_dos_attributes_send, .get_dos_attributes_recv_fn = vfs_not_implemented_get_dos_attributes_recv, .fget_dos_attributes_fn = vfs_gpfs_fget_dos_attributes, .fset_dos_attributes_fn = vfs_gpfs_fset_dos_attributes, .fget_nt_acl_fn = gpfsacl_fget_nt_acl, .fset_nt_acl_fn = gpfsacl_fset_nt_acl, .sys_acl_get_fd_fn = gpfsacl_sys_acl_get_fd, .sys_acl_blob_get_fd_fn = gpfsacl_sys_acl_blob_get_fd, .sys_acl_set_fd_fn = gpfsacl_sys_acl_set_fd, .sys_acl_delete_def_fd_fn = gpfsacl_sys_acl_delete_def_fd, .fchmod_fn = vfs_gpfs_fchmod, .close_fn = vfs_gpfs_close, .stat_fn = vfs_gpfs_stat, .lstat_fn = vfs_gpfs_lstat, .fntimes_fn = vfs_gpfs_fntimes, .aio_force_fn = vfs_gpfs_aio_force, .sendfile_fn = vfs_gpfs_sendfile, .fallocate_fn = vfs_gpfs_fallocate, .openat_fn = vfs_gpfs_openat, .pread_fn = vfs_gpfs_pread, .pread_send_fn = vfs_gpfs_pread_send, .pread_recv_fn = vfs_gpfs_pread_recv, .pwrite_fn = vfs_gpfs_pwrite, .pwrite_send_fn = vfs_gpfs_pwrite_send, .pwrite_recv_fn = vfs_gpfs_pwrite_recv, .ftruncate_fn = vfs_gpfs_ftruncate }; static_decl_vfs; NTSTATUS vfs_gpfs_init(TALLOC_CTX *ctx) { int ret; ret = gpfswrap_init(); if (ret != 0) { DEBUG(1, ("Could not initialize GPFS library wrapper\n")); } return smb_register_vfs(SMB_VFS_INTERFACE_VERSION, "gpfs", &vfs_gpfs_fns); }