static NTSTATUS smbcli_setup_unix(struct smbcli_tree *tree)
{
union smb_fsinfo fsinfo;
union smb_setfsinfo set_fsinfo;
NTSTATUS status;
ZERO_STRUCT(fsinfo);
ZERO_STRUCT(set_fsinfo);
fsinfo.generic.level = RAW_QFS_UNIX_INFO;
status = smb_raw_fsinfo(tree, NULL, &fsinfo);
if (!NT_STATUS_IS_OK(status)) {
printf("smb_raw_fsinfo failed %s\n",
nt_errstr(status));
return status;
}
set_fsinfo.generic.level = RAW_SETFS_UNIX_INFO;
set_fsinfo.unix_info.in.major_version = fsinfo.unix_info.out.major_version;
set_fsinfo.unix_info.in.minor_version = fsinfo.unix_info.out.minor_version;
set_fsinfo.unix_info.in.capability = fsinfo.unix_info.out.capability;
status = smb_raw_setfsinfo(tree, NULL, &set_fsinfo);
if (!NT_STATUS_IS_OK(status)) {
printf("smb_raw_setfsinfo failed %s\n",
nt_errstr(status));
}
return status;
}
/*
return filesystem space info
*/
static NTSTATUS cvfs_fsinfo(struct ntvfs_module_context *ntvfs,
struct ntvfs_request *req, union smb_fsinfo *fs)
{
struct cvfs_private *p = ntvfs->private_data;
struct smbcli_request *c_req;
SETUP_PID;
if (!(req->async_states->state & NTVFS_ASYNC_STATE_MAY_ASYNC)) {
return smb_raw_fsinfo(p->tree, req, fs);
}
c_req = smb_raw_fsinfo_send(p->tree, req, fs);
ASYNC_RECV_TAIL(fs, async_fsinfo);
}
/* basic testing of all RAW_QFS_* calls
for each call we test that it succeeds, and where possible test
for consistency between the calls.
Some of the consistency tests assume that the target filesystem is
quiescent, which is sometimes hard to achieve
*/
bool torture_raw_qfsinfo(struct torture_context *torture,
struct smbcli_state *cli)
{
int i;
bool ret = true;
int count;
union smb_fsinfo *s1, *s2;
/* scan all the levels, pulling the results */
for (i=0; levels[i].name; i++) {
torture_comment(torture, "Running level %s\n", levels[i].name);
levels[i].fsinfo.generic.level = levels[i].level;
levels[i].status = smb_raw_fsinfo(cli->tree, torture, &levels[i].fsinfo);
}
/* check for completely broken levels */
for (count=i=0; levels[i].name; i++) {
uint32_t cap = cli->transport->negotiate.capabilities;
/* see if this server claims to support this level */
if ((cap & levels[i].capability_mask) != levels[i].capability_mask) {
continue;
}
if (!NT_STATUS_IS_OK(levels[i].status)) {
printf("ERROR: level %s failed - %s\n",
levels[i].name, nt_errstr(levels[i].status));
count++;
}
}
if (count != 0) {
torture_comment(torture, "%d levels failed\n", count);
torture_assert(torture, count > 13, "too many level failures - giving up");
}
torture_comment(torture, "check for correct aliases\n");
s1 = find("SIZE_INFO");
s2 = find("SIZE_INFORMATION");
if (s1 && s2) {
VAL_EQUAL(size_info, total_alloc_units, size_info, total_alloc_units);
VAL_APPROX_EQUAL(size_info, avail_alloc_units, size_info, avail_alloc_units);
VAL_EQUAL(size_info, sectors_per_unit, size_info, sectors_per_unit);
VAL_EQUAL(size_info, bytes_per_sector, size_info, bytes_per_sector);
}
s1 = find("DEVICE_INFO");
s2 = find("DEVICE_INFORMATION");
if (s1 && s2) {
VAL_EQUAL(device_info, device_type, device_info, device_type);
VAL_EQUAL(device_info, characteristics, device_info, characteristics);
}
s1 = find("VOLUME_INFO");
s2 = find("VOLUME_INFORMATION");
if (s1 && s2) {
STRUCT_EQUAL(volume_info, create_time, volume_info, create_time);
VAL_EQUAL (volume_info, serial_number, volume_info, serial_number);
STR_EQUAL (volume_info, volume_name.s, volume_info, volume_name.s);
torture_comment(torture, "volume_info.volume_name = '%s'\n", s1->volume_info.out.volume_name.s);
}
s1 = find("ATTRIBUTE_INFO");
s2 = find("ATTRIBUTE_INFORMATION");
if (s1 && s2) {
VAL_EQUAL(attribute_info, fs_attr,
attribute_info, fs_attr);
VAL_EQUAL(attribute_info, max_file_component_length,
attribute_info, max_file_component_length);
STR_EQUAL(attribute_info, fs_type.s, attribute_info, fs_type.s);
torture_comment(torture, "attribute_info.fs_type = '%s'\n", s1->attribute_info.out.fs_type.s);
}
torture_comment(torture, "check for consistent disk sizes\n");
s1 = find("DSKATTR");
s2 = find("ALLOCATION");
if (s1 && s2) {
double size1, size2;
double scale = s1->dskattr.out.blocks_per_unit * s1->dskattr.out.block_size;
size1 = 1.0 *
s1->dskattr.out.units_total *
s1->dskattr.out.blocks_per_unit *
s1->dskattr.out.block_size / scale;
size2 = 1.0 *
s2->allocation.out.sectors_per_unit *
s2->allocation.out.total_alloc_units *
s2->allocation.out.bytes_per_sector / scale;
if (abs(size1 - size2) > 1) {
printf("Inconsistent total size in DSKATTR and ALLOCATION - size1=%.0f size2=%.0f\n",
size1, size2);
ret = false;
}
torture_comment(torture, "total disk = %.0f MB\n", size1*scale/1.0e6);
}
torture_comment(torture, "check consistent free disk space\n");
s1 = find("DSKATTR");
s2 = find("ALLOCATION");
if (s1 && s2) {
double size1, size2;
double scale = s1->dskattr.out.blocks_per_unit * s1->dskattr.out.block_size;
size1 = 1.0 *
s1->dskattr.out.units_free *
s1->dskattr.out.blocks_per_unit *
s1->dskattr.out.block_size / scale;
size2 = 1.0 *
s2->allocation.out.sectors_per_unit *
s2->allocation.out.avail_alloc_units *
s2->allocation.out.bytes_per_sector / scale;
if (abs(size1 - size2) > 1) {
printf("Inconsistent avail size in DSKATTR and ALLOCATION - size1=%.0f size2=%.0f\n",
size1, size2);
ret = false;
}
torture_comment(torture, "free disk = %.0f MB\n", size1*scale/1.0e6);
}
torture_comment(torture, "volume info consistency\n");
s1 = find("VOLUME");
s2 = find("VOLUME_INFO");
if (s1 && s2) {
VAL_EQUAL(volume, serial_number, volume_info, serial_number);
STR_EQUAL(volume, volume_name.s, volume_info, volume_name.s);
}
/* disk size consistency - notice that 'avail_alloc_units' maps to the caller
available allocation units, not the total */
s1 = find("SIZE_INFO");
s2 = find("FULL_SIZE_INFORMATION");
if (s1 && s2) {
VAL_EQUAL(size_info, total_alloc_units, full_size_information, total_alloc_units);
VAL_APPROX_EQUAL(size_info, avail_alloc_units, full_size_information, call_avail_alloc_units);
VAL_EQUAL(size_info, sectors_per_unit, full_size_information, sectors_per_unit);
VAL_EQUAL(size_info, bytes_per_sector, full_size_information, bytes_per_sector);
}
printf("check for non-zero unknown fields\n");
s1 = find("QUOTA_INFORMATION");
if (s1) {
VAL_UNKNOWN(quota_information, unknown[0]);
VAL_UNKNOWN(quota_information, unknown[1]);
VAL_UNKNOWN(quota_information, unknown[2]);
}
s1 = find("OBJECTID_INFORMATION");
if (s1) {
VAL_UNKNOWN(objectid_information, unknown[0]);
VAL_UNKNOWN(objectid_information, unknown[1]);
VAL_UNKNOWN(objectid_information, unknown[2]);
VAL_UNKNOWN(objectid_information, unknown[3]);
VAL_UNKNOWN(objectid_information, unknown[4]);
VAL_UNKNOWN(objectid_information, unknown[5]);
}
#define STR_CHECK(sname, stype, field, flags) do { \
s1 = find(sname); \
if (s1) { \
if (s1->stype.out.field.s && wire_bad_flags(&s1->stype.out.field, flags, cli->transport)) { \
printf("(%d) incorrect string termination in %s/%s\n", \
__LINE__, #stype, #field); \
ret = false; \
} \
}} while (0)
torture_comment(torture, "check for correct termination\n");
STR_CHECK("VOLUME", volume, volume_name, 0);
STR_CHECK("VOLUME_INFO", volume_info, volume_name, STR_UNICODE);
STR_CHECK("VOLUME_INFORMATION", volume_info, volume_name, STR_UNICODE);
STR_CHECK("ATTRIBUTE_INFO", attribute_info, fs_type, STR_UNICODE);
STR_CHECK("ATTRIBUTE_INFORMATION", attribute_info, fs_type, STR_UNICODE);
return ret;
}
