qemu/tests/qtest/virtio-9p-test.c
Christian Schoenebeck 653daf3897 tests/9pfs: add local Tmkdir test
This test case uses the 9pfs 'local' driver to create a directory
and then checks if the expected directory was actually created
(as real directory) on host side.

This patch introduces a custom split() implementation, because
the test code requires non empty array elements as result. For
that reason g_strsplit() would not be a good alternative, as
it would require additional filter code for reshuffling the
array, and the resulting code would be even more complex than
this split() function.

Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com>
Message-Id: <be342f236842272275f65dbe05587f0a5409ad77.1602182956.git.qemu_oss@crudebyte.com>
Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com>
2020-10-19 14:25:40 +02:00

1079 lines
28 KiB
C

/*
* QTest testcase for VirtIO 9P
*
* Copyright (c) 2014 SUSE LINUX Products GmbH
*
* This work is licensed under the terms of the GNU GPL, version 2 or later.
* See the COPYING file in the top-level directory.
*/
#include "qemu/osdep.h"
#include "libqtest-single.h"
#include "qemu/module.h"
#include "hw/9pfs/9p.h"
#include "hw/9pfs/9p-synth.h"
#include "libqos/virtio-9p.h"
#include "libqos/qgraph.h"
#define QVIRTIO_9P_TIMEOUT_US (10 * 1000 * 1000)
static QGuestAllocator *alloc;
/*
* Used to auto generate new fids. Start with arbitrary high value to avoid
* collision with hard coded fids in basic test code.
*/
static uint32_t fid_generator = 1000;
static uint32_t genfid(void)
{
return fid_generator++;
}
/**
* Splits the @a in string by @a delim into individual (non empty) strings
* and outputs them to @a out. The output array @a out is NULL terminated.
*
* Output array @a out must be freed by calling split_free().
*
* @returns number of individual elements in output array @a out (without the
* final NULL terminating element)
*/
static int split(const char *in, const char *delim, char ***out)
{
int n = 0, i = 0;
char *tmp, *p;
tmp = g_strdup(in);
for (p = strtok(tmp, delim); p != NULL; p = strtok(NULL, delim)) {
if (strlen(p) > 0) {
++n;
}
}
g_free(tmp);
*out = g_new0(char *, n + 1); /* last element NULL delimiter */
tmp = g_strdup(in);
for (p = strtok(tmp, delim); p != NULL; p = strtok(NULL, delim)) {
if (strlen(p) > 0) {
(*out)[i++] = g_strdup(p);
}
}
g_free(tmp);
return n;
}
static void split_free(char ***out)
{
int i;
for (i = 0; (*out)[i]; ++i) {
g_free((*out)[i]);
}
g_free(*out);
*out = NULL;
}
static void pci_config(void *obj, void *data, QGuestAllocator *t_alloc)
{
QVirtio9P *v9p = obj;
alloc = t_alloc;
size_t tag_len = qvirtio_config_readw(v9p->vdev, 0);
char *tag;
int i;
g_assert_cmpint(tag_len, ==, strlen(MOUNT_TAG));
tag = g_malloc(tag_len);
for (i = 0; i < tag_len; i++) {
tag[i] = qvirtio_config_readb(v9p->vdev, i + 2);
}
g_assert_cmpmem(tag, tag_len, MOUNT_TAG, tag_len);
g_free(tag);
}
#define P9_MAX_SIZE 4096 /* Max size of a T-message or R-message */
typedef struct {
QTestState *qts;
QVirtio9P *v9p;
uint16_t tag;
uint64_t t_msg;
uint32_t t_size;
uint64_t r_msg;
/* No r_size, it is hardcoded to P9_MAX_SIZE */
size_t t_off;
size_t r_off;
uint32_t free_head;
} P9Req;
static void v9fs_memwrite(P9Req *req, const void *addr, size_t len)
{
qtest_memwrite(req->qts, req->t_msg + req->t_off, addr, len);
req->t_off += len;
}
static void v9fs_memskip(P9Req *req, size_t len)
{
req->r_off += len;
}
static void v9fs_memread(P9Req *req, void *addr, size_t len)
{
qtest_memread(req->qts, req->r_msg + req->r_off, addr, len);
req->r_off += len;
}
static void v9fs_uint8_read(P9Req *req, uint8_t *val)
{
v9fs_memread(req, val, 1);
}
static void v9fs_uint16_write(P9Req *req, uint16_t val)
{
uint16_t le_val = cpu_to_le16(val);
v9fs_memwrite(req, &le_val, 2);
}
static void v9fs_uint16_read(P9Req *req, uint16_t *val)
{
v9fs_memread(req, val, 2);
le16_to_cpus(val);
}
static void v9fs_uint32_write(P9Req *req, uint32_t val)
{
uint32_t le_val = cpu_to_le32(val);
v9fs_memwrite(req, &le_val, 4);
}
static void v9fs_uint64_write(P9Req *req, uint64_t val)
{
uint64_t le_val = cpu_to_le64(val);
v9fs_memwrite(req, &le_val, 8);
}
static void v9fs_uint32_read(P9Req *req, uint32_t *val)
{
v9fs_memread(req, val, 4);
le32_to_cpus(val);
}
static void v9fs_uint64_read(P9Req *req, uint64_t *val)
{
v9fs_memread(req, val, 8);
le64_to_cpus(val);
}
/* len[2] string[len] */
static uint16_t v9fs_string_size(const char *string)
{
size_t len = strlen(string);
g_assert_cmpint(len, <=, UINT16_MAX - 2);
return 2 + len;
}
static void v9fs_string_write(P9Req *req, const char *string)
{
int len = strlen(string);
g_assert_cmpint(len, <=, UINT16_MAX);
v9fs_uint16_write(req, (uint16_t) len);
v9fs_memwrite(req, string, len);
}
static void v9fs_string_read(P9Req *req, uint16_t *len, char **string)
{
uint16_t local_len;
v9fs_uint16_read(req, &local_len);
if (len) {
*len = local_len;
}
if (string) {
*string = g_malloc(local_len + 1);
v9fs_memread(req, *string, local_len);
(*string)[local_len] = 0;
} else {
v9fs_memskip(req, local_len);
}
}
typedef struct {
uint32_t size;
uint8_t id;
uint16_t tag;
} QEMU_PACKED P9Hdr;
static P9Req *v9fs_req_init(QVirtio9P *v9p, uint32_t size, uint8_t id,
uint16_t tag)
{
P9Req *req = g_new0(P9Req, 1);
uint32_t total_size = 7; /* 9P header has well-known size of 7 bytes */
P9Hdr hdr = {
.id = id,
.tag = cpu_to_le16(tag)
};
g_assert_cmpint(total_size, <=, UINT32_MAX - size);
total_size += size;
hdr.size = cpu_to_le32(total_size);
g_assert_cmpint(total_size, <=, P9_MAX_SIZE);
req->qts = global_qtest;
req->v9p = v9p;
req->t_size = total_size;
req->t_msg = guest_alloc(alloc, req->t_size);
v9fs_memwrite(req, &hdr, 7);
req->tag = tag;
return req;
}
static void v9fs_req_send(P9Req *req)
{
QVirtio9P *v9p = req->v9p;
req->r_msg = guest_alloc(alloc, P9_MAX_SIZE);
req->free_head = qvirtqueue_add(req->qts, v9p->vq, req->t_msg, req->t_size,
false, true);
qvirtqueue_add(req->qts, v9p->vq, req->r_msg, P9_MAX_SIZE, true, false);
qvirtqueue_kick(req->qts, v9p->vdev, v9p->vq, req->free_head);
req->t_off = 0;
}
static const char *rmessage_name(uint8_t id)
{
return
id == P9_RLERROR ? "RLERROR" :
id == P9_RVERSION ? "RVERSION" :
id == P9_RATTACH ? "RATTACH" :
id == P9_RWALK ? "RWALK" :
id == P9_RLOPEN ? "RLOPEN" :
id == P9_RWRITE ? "RWRITE" :
id == P9_RMKDIR ? "RMKDIR" :
id == P9_RFLUSH ? "RFLUSH" :
id == P9_RREADDIR ? "READDIR" :
"<unknown>";
}
static void v9fs_req_wait_for_reply(P9Req *req, uint32_t *len)
{
QVirtio9P *v9p = req->v9p;
qvirtio_wait_used_elem(req->qts, v9p->vdev, v9p->vq, req->free_head, len,
QVIRTIO_9P_TIMEOUT_US);
}
static void v9fs_req_recv(P9Req *req, uint8_t id)
{
P9Hdr hdr;
v9fs_memread(req, &hdr, 7);
hdr.size = ldl_le_p(&hdr.size);
hdr.tag = lduw_le_p(&hdr.tag);
g_assert_cmpint(hdr.size, >=, 7);
g_assert_cmpint(hdr.size, <=, P9_MAX_SIZE);
g_assert_cmpint(hdr.tag, ==, req->tag);
if (hdr.id != id) {
g_printerr("Received response %d (%s) instead of %d (%s)\n",
hdr.id, rmessage_name(hdr.id), id, rmessage_name(id));
if (hdr.id == P9_RLERROR) {
uint32_t err;
v9fs_uint32_read(req, &err);
g_printerr("Rlerror has errno %d (%s)\n", err, strerror(err));
}
}
g_assert_cmpint(hdr.id, ==, id);
}
static void v9fs_req_free(P9Req *req)
{
guest_free(alloc, req->t_msg);
guest_free(alloc, req->r_msg);
g_free(req);
}
/* size[4] Rlerror tag[2] ecode[4] */
static void v9fs_rlerror(P9Req *req, uint32_t *err)
{
v9fs_req_recv(req, P9_RLERROR);
v9fs_uint32_read(req, err);
v9fs_req_free(req);
}
/* size[4] Tversion tag[2] msize[4] version[s] */
static P9Req *v9fs_tversion(QVirtio9P *v9p, uint32_t msize, const char *version,
uint16_t tag)
{
P9Req *req;
uint32_t body_size = 4;
uint16_t string_size = v9fs_string_size(version);
g_assert_cmpint(body_size, <=, UINT32_MAX - string_size);
body_size += string_size;
req = v9fs_req_init(v9p, body_size, P9_TVERSION, tag);
v9fs_uint32_write(req, msize);
v9fs_string_write(req, version);
v9fs_req_send(req);
return req;
}
/* size[4] Rversion tag[2] msize[4] version[s] */
static void v9fs_rversion(P9Req *req, uint16_t *len, char **version)
{
uint32_t msize;
v9fs_req_recv(req, P9_RVERSION);
v9fs_uint32_read(req, &msize);
g_assert_cmpint(msize, ==, P9_MAX_SIZE);
if (len || version) {
v9fs_string_read(req, len, version);
}
v9fs_req_free(req);
}
/* size[4] Tattach tag[2] fid[4] afid[4] uname[s] aname[s] n_uname[4] */
static P9Req *v9fs_tattach(QVirtio9P *v9p, uint32_t fid, uint32_t n_uname,
uint16_t tag)
{
const char *uname = ""; /* ignored by QEMU */
const char *aname = ""; /* ignored by QEMU */
P9Req *req = v9fs_req_init(v9p, 4 + 4 + 2 + 2 + 4, P9_TATTACH, tag);
v9fs_uint32_write(req, fid);
v9fs_uint32_write(req, P9_NOFID);
v9fs_string_write(req, uname);
v9fs_string_write(req, aname);
v9fs_uint32_write(req, n_uname);
v9fs_req_send(req);
return req;
}
typedef char v9fs_qid[13];
/* size[4] Rattach tag[2] qid[13] */
static void v9fs_rattach(P9Req *req, v9fs_qid *qid)
{
v9fs_req_recv(req, P9_RATTACH);
if (qid) {
v9fs_memread(req, qid, 13);
}
v9fs_req_free(req);
}
/* size[4] Twalk tag[2] fid[4] newfid[4] nwname[2] nwname*(wname[s]) */
static P9Req *v9fs_twalk(QVirtio9P *v9p, uint32_t fid, uint32_t newfid,
uint16_t nwname, char *const wnames[], uint16_t tag)
{
P9Req *req;
int i;
uint32_t body_size = 4 + 4 + 2;
for (i = 0; i < nwname; i++) {
uint16_t wname_size = v9fs_string_size(wnames[i]);
g_assert_cmpint(body_size, <=, UINT32_MAX - wname_size);
body_size += wname_size;
}
req = v9fs_req_init(v9p, body_size, P9_TWALK, tag);
v9fs_uint32_write(req, fid);
v9fs_uint32_write(req, newfid);
v9fs_uint16_write(req, nwname);
for (i = 0; i < nwname; i++) {
v9fs_string_write(req, wnames[i]);
}
v9fs_req_send(req);
return req;
}
/* size[4] Rwalk tag[2] nwqid[2] nwqid*(wqid[13]) */
static void v9fs_rwalk(P9Req *req, uint16_t *nwqid, v9fs_qid **wqid)
{
uint16_t local_nwqid;
v9fs_req_recv(req, P9_RWALK);
v9fs_uint16_read(req, &local_nwqid);
if (nwqid) {
*nwqid = local_nwqid;
}
if (wqid) {
*wqid = g_malloc(local_nwqid * 13);
v9fs_memread(req, *wqid, local_nwqid * 13);
}
v9fs_req_free(req);
}
/* size[4] Treaddir tag[2] fid[4] offset[8] count[4] */
static P9Req *v9fs_treaddir(QVirtio9P *v9p, uint32_t fid, uint64_t offset,
uint32_t count, uint16_t tag)
{
P9Req *req;
req = v9fs_req_init(v9p, 4 + 8 + 4, P9_TREADDIR, tag);
v9fs_uint32_write(req, fid);
v9fs_uint64_write(req, offset);
v9fs_uint32_write(req, count);
v9fs_req_send(req);
return req;
}
struct V9fsDirent {
v9fs_qid qid;
uint64_t offset;
uint8_t type;
char *name;
struct V9fsDirent *next;
};
/* size[4] Rreaddir tag[2] count[4] data[count] */
static void v9fs_rreaddir(P9Req *req, uint32_t *count, uint32_t *nentries,
struct V9fsDirent **entries)
{
uint32_t local_count;
struct V9fsDirent *e = NULL;
uint16_t slen;
uint32_t n = 0;
v9fs_req_recv(req, P9_RREADDIR);
v9fs_uint32_read(req, &local_count);
if (count) {
*count = local_count;
}
for (int32_t togo = (int32_t)local_count;
togo >= 13 + 8 + 1 + 2;
togo -= 13 + 8 + 1 + 2 + slen, ++n)
{
if (!e) {
e = g_malloc(sizeof(struct V9fsDirent));
if (entries) {
*entries = e;
}
} else {
e = e->next = g_malloc(sizeof(struct V9fsDirent));
}
e->next = NULL;
/* qid[13] offset[8] type[1] name[s] */
v9fs_memread(req, &e->qid, 13);
v9fs_uint64_read(req, &e->offset);
v9fs_uint8_read(req, &e->type);
v9fs_string_read(req, &slen, &e->name);
}
if (nentries) {
*nentries = n;
}
v9fs_req_free(req);
}
static void v9fs_free_dirents(struct V9fsDirent *e)
{
struct V9fsDirent *next = NULL;
for (; e; e = next) {
next = e->next;
g_free(e->name);
g_free(e);
}
}
/* size[4] Tlopen tag[2] fid[4] flags[4] */
static P9Req *v9fs_tlopen(QVirtio9P *v9p, uint32_t fid, uint32_t flags,
uint16_t tag)
{
P9Req *req;
req = v9fs_req_init(v9p, 4 + 4, P9_TLOPEN, tag);
v9fs_uint32_write(req, fid);
v9fs_uint32_write(req, flags);
v9fs_req_send(req);
return req;
}
/* size[4] Rlopen tag[2] qid[13] iounit[4] */
static void v9fs_rlopen(P9Req *req, v9fs_qid *qid, uint32_t *iounit)
{
v9fs_req_recv(req, P9_RLOPEN);
if (qid) {
v9fs_memread(req, qid, 13);
} else {
v9fs_memskip(req, 13);
}
if (iounit) {
v9fs_uint32_read(req, iounit);
}
v9fs_req_free(req);
}
/* size[4] Twrite tag[2] fid[4] offset[8] count[4] data[count] */
static P9Req *v9fs_twrite(QVirtio9P *v9p, uint32_t fid, uint64_t offset,
uint32_t count, const void *data, uint16_t tag)
{
P9Req *req;
uint32_t body_size = 4 + 8 + 4;
g_assert_cmpint(body_size, <=, UINT32_MAX - count);
body_size += count;
req = v9fs_req_init(v9p, body_size, P9_TWRITE, tag);
v9fs_uint32_write(req, fid);
v9fs_uint64_write(req, offset);
v9fs_uint32_write(req, count);
v9fs_memwrite(req, data, count);
v9fs_req_send(req);
return req;
}
/* size[4] Rwrite tag[2] count[4] */
static void v9fs_rwrite(P9Req *req, uint32_t *count)
{
v9fs_req_recv(req, P9_RWRITE);
if (count) {
v9fs_uint32_read(req, count);
}
v9fs_req_free(req);
}
/* size[4] Tflush tag[2] oldtag[2] */
static P9Req *v9fs_tflush(QVirtio9P *v9p, uint16_t oldtag, uint16_t tag)
{
P9Req *req;
req = v9fs_req_init(v9p, 2, P9_TFLUSH, tag);
v9fs_uint32_write(req, oldtag);
v9fs_req_send(req);
return req;
}
/* size[4] Rflush tag[2] */
static void v9fs_rflush(P9Req *req)
{
v9fs_req_recv(req, P9_RFLUSH);
v9fs_req_free(req);
}
static void fs_version(void *obj, void *data, QGuestAllocator *t_alloc)
{
QVirtio9P *v9p = obj;
alloc = t_alloc;
const char *version = "9P2000.L";
uint16_t server_len;
char *server_version;
P9Req *req;
req = v9fs_tversion(v9p, P9_MAX_SIZE, version, P9_NOTAG);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rversion(req, &server_len, &server_version);
g_assert_cmpmem(server_version, server_len, version, strlen(version));
g_free(server_version);
}
static void fs_attach(void *obj, void *data, QGuestAllocator *t_alloc)
{
QVirtio9P *v9p = obj;
alloc = t_alloc;
P9Req *req;
fs_version(v9p, NULL, t_alloc);
req = v9fs_tattach(v9p, 0, getuid(), 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rattach(req, NULL);
}
static void fs_walk(void *obj, void *data, QGuestAllocator *t_alloc)
{
QVirtio9P *v9p = obj;
alloc = t_alloc;
char *wnames[P9_MAXWELEM];
uint16_t nwqid;
v9fs_qid *wqid;
int i;
P9Req *req;
for (i = 0; i < P9_MAXWELEM; i++) {
wnames[i] = g_strdup_printf(QTEST_V9FS_SYNTH_WALK_FILE, i);
}
fs_attach(v9p, NULL, t_alloc);
req = v9fs_twalk(v9p, 0, 1, P9_MAXWELEM, wnames, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rwalk(req, &nwqid, &wqid);
g_assert_cmpint(nwqid, ==, P9_MAXWELEM);
for (i = 0; i < P9_MAXWELEM; i++) {
g_free(wnames[i]);
}
g_free(wqid);
}
static bool fs_dirents_contain_name(struct V9fsDirent *e, const char* name)
{
for (; e; e = e->next) {
if (!strcmp(e->name, name)) {
return true;
}
}
return false;
}
/* size[4] Tmkdir tag[2] dfid[4] name[s] mode[4] gid[4] */
static P9Req *v9fs_tmkdir(QVirtio9P *v9p, uint32_t dfid, const char *name,
uint32_t mode, uint32_t gid, uint16_t tag)
{
P9Req *req;
uint32_t body_size = 4 + 4 + 4;
uint16_t string_size = v9fs_string_size(name);
g_assert_cmpint(body_size, <=, UINT32_MAX - string_size);
body_size += string_size;
req = v9fs_req_init(v9p, body_size, P9_TMKDIR, tag);
v9fs_uint32_write(req, dfid);
v9fs_string_write(req, name);
v9fs_uint32_write(req, mode);
v9fs_uint32_write(req, gid);
v9fs_req_send(req);
return req;
}
/* size[4] Rmkdir tag[2] qid[13] */
static void v9fs_rmkdir(P9Req *req, v9fs_qid *qid)
{
v9fs_req_recv(req, P9_RMKDIR);
if (qid) {
v9fs_memread(req, qid, 13);
} else {
v9fs_memskip(req, 13);
}
v9fs_req_free(req);
}
/* basic readdir test where reply fits into a single response message */
static void fs_readdir(void *obj, void *data, QGuestAllocator *t_alloc)
{
QVirtio9P *v9p = obj;
alloc = t_alloc;
char *const wnames[] = { g_strdup(QTEST_V9FS_SYNTH_READDIR_DIR) };
uint16_t nqid;
v9fs_qid qid;
uint32_t count, nentries;
struct V9fsDirent *entries = NULL;
P9Req *req;
fs_attach(v9p, NULL, t_alloc);
req = v9fs_twalk(v9p, 0, 1, 1, wnames, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rwalk(req, &nqid, NULL);
g_assert_cmpint(nqid, ==, 1);
req = v9fs_tlopen(v9p, 1, O_DIRECTORY, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rlopen(req, &qid, NULL);
/*
* submit count = msize - 11, because 11 is the header size of Rreaddir
*/
req = v9fs_treaddir(v9p, 1, 0, P9_MAX_SIZE - 11, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rreaddir(req, &count, &nentries, &entries);
/*
* Assuming msize (P9_MAX_SIZE) is large enough so we can retrieve all
* dir entries with only one readdir request.
*/
g_assert_cmpint(
nentries, ==,
QTEST_V9FS_SYNTH_READDIR_NFILES + 2 /* "." and ".." */
);
/*
* Check all file names exist in returned entries, ignore their order
* though.
*/
g_assert_cmpint(fs_dirents_contain_name(entries, "."), ==, true);
g_assert_cmpint(fs_dirents_contain_name(entries, ".."), ==, true);
for (int i = 0; i < QTEST_V9FS_SYNTH_READDIR_NFILES; ++i) {
char *name = g_strdup_printf(QTEST_V9FS_SYNTH_READDIR_FILE, i);
g_assert_cmpint(fs_dirents_contain_name(entries, name), ==, true);
g_free(name);
}
v9fs_free_dirents(entries);
g_free(wnames[0]);
}
/* readdir test where overall request is split over several messages */
static void fs_readdir_split(void *obj, void *data, QGuestAllocator *t_alloc,
uint32_t count)
{
QVirtio9P *v9p = obj;
alloc = t_alloc;
char *const wnames[] = { g_strdup(QTEST_V9FS_SYNTH_READDIR_DIR) };
uint16_t nqid;
v9fs_qid qid;
uint32_t nentries, npartialentries;
struct V9fsDirent *entries, *tail, *partialentries;
P9Req *req;
int fid;
uint64_t offset;
fs_attach(v9p, NULL, t_alloc);
fid = 1;
offset = 0;
entries = NULL;
nentries = 0;
tail = NULL;
req = v9fs_twalk(v9p, 0, fid, 1, wnames, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rwalk(req, &nqid, NULL);
g_assert_cmpint(nqid, ==, 1);
req = v9fs_tlopen(v9p, fid, O_DIRECTORY, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rlopen(req, &qid, NULL);
/*
* send as many Treaddir requests as required to get all directory
* entries
*/
while (true) {
npartialentries = 0;
partialentries = NULL;
req = v9fs_treaddir(v9p, fid, offset, count, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rreaddir(req, &count, &npartialentries, &partialentries);
if (npartialentries > 0 && partialentries) {
if (!entries) {
entries = partialentries;
nentries = npartialentries;
tail = partialentries;
} else {
tail->next = partialentries;
nentries += npartialentries;
}
while (tail->next) {
tail = tail->next;
}
offset = tail->offset;
} else {
break;
}
}
g_assert_cmpint(
nentries, ==,
QTEST_V9FS_SYNTH_READDIR_NFILES + 2 /* "." and ".." */
);
/*
* Check all file names exist in returned entries, ignore their order
* though.
*/
g_assert_cmpint(fs_dirents_contain_name(entries, "."), ==, true);
g_assert_cmpint(fs_dirents_contain_name(entries, ".."), ==, true);
for (int i = 0; i < QTEST_V9FS_SYNTH_READDIR_NFILES; ++i) {
char *name = g_strdup_printf(QTEST_V9FS_SYNTH_READDIR_FILE, i);
g_assert_cmpint(fs_dirents_contain_name(entries, name), ==, true);
g_free(name);
}
v9fs_free_dirents(entries);
g_free(wnames[0]);
}
static void fs_walk_no_slash(void *obj, void *data, QGuestAllocator *t_alloc)
{
QVirtio9P *v9p = obj;
alloc = t_alloc;
char *const wnames[] = { g_strdup(" /") };
P9Req *req;
uint32_t err;
fs_attach(v9p, NULL, t_alloc);
req = v9fs_twalk(v9p, 0, 1, 1, wnames, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rlerror(req, &err);
g_assert_cmpint(err, ==, ENOENT);
g_free(wnames[0]);
}
static void fs_walk_dotdot(void *obj, void *data, QGuestAllocator *t_alloc)
{
QVirtio9P *v9p = obj;
alloc = t_alloc;
char *const wnames[] = { g_strdup("..") };
v9fs_qid root_qid, *wqid;
P9Req *req;
fs_version(v9p, NULL, t_alloc);
req = v9fs_tattach(v9p, 0, getuid(), 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rattach(req, &root_qid);
req = v9fs_twalk(v9p, 0, 1, 1, wnames, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rwalk(req, NULL, &wqid); /* We now we'll get one qid */
g_assert_cmpmem(&root_qid, 13, wqid[0], 13);
g_free(wqid);
g_free(wnames[0]);
}
static void fs_lopen(void *obj, void *data, QGuestAllocator *t_alloc)
{
QVirtio9P *v9p = obj;
alloc = t_alloc;
char *const wnames[] = { g_strdup(QTEST_V9FS_SYNTH_LOPEN_FILE) };
P9Req *req;
fs_attach(v9p, NULL, t_alloc);
req = v9fs_twalk(v9p, 0, 1, 1, wnames, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rwalk(req, NULL, NULL);
req = v9fs_tlopen(v9p, 1, O_WRONLY, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rlopen(req, NULL, NULL);
g_free(wnames[0]);
}
static void fs_write(void *obj, void *data, QGuestAllocator *t_alloc)
{
QVirtio9P *v9p = obj;
alloc = t_alloc;
static const uint32_t write_count = P9_MAX_SIZE / 2;
char *const wnames[] = { g_strdup(QTEST_V9FS_SYNTH_WRITE_FILE) };
char *buf = g_malloc0(write_count);
uint32_t count;
P9Req *req;
fs_attach(v9p, NULL, t_alloc);
req = v9fs_twalk(v9p, 0, 1, 1, wnames, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rwalk(req, NULL, NULL);
req = v9fs_tlopen(v9p, 1, O_WRONLY, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rlopen(req, NULL, NULL);
req = v9fs_twrite(v9p, 1, 0, write_count, buf, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rwrite(req, &count);
g_assert_cmpint(count, ==, write_count);
g_free(buf);
g_free(wnames[0]);
}
static void fs_flush_success(void *obj, void *data, QGuestAllocator *t_alloc)
{
QVirtio9P *v9p = obj;
alloc = t_alloc;
char *const wnames[] = { g_strdup(QTEST_V9FS_SYNTH_FLUSH_FILE) };
P9Req *req, *flush_req;
uint32_t reply_len;
uint8_t should_block;
fs_attach(v9p, NULL, t_alloc);
req = v9fs_twalk(v9p, 0, 1, 1, wnames, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rwalk(req, NULL, NULL);
req = v9fs_tlopen(v9p, 1, O_WRONLY, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rlopen(req, NULL, NULL);
/* This will cause the 9p server to try to write data to the backend,
* until the write request gets cancelled.
*/
should_block = 1;
req = v9fs_twrite(v9p, 1, 0, sizeof(should_block), &should_block, 0);
flush_req = v9fs_tflush(v9p, req->tag, 1);
/* The write request is supposed to be flushed: the server should just
* mark the write request as used and reply to the flush request.
*/
v9fs_req_wait_for_reply(req, &reply_len);
g_assert_cmpint(reply_len, ==, 0);
v9fs_req_free(req);
v9fs_rflush(flush_req);
g_free(wnames[0]);
}
static void fs_flush_ignored(void *obj, void *data, QGuestAllocator *t_alloc)
{
QVirtio9P *v9p = obj;
alloc = t_alloc;
char *const wnames[] = { g_strdup(QTEST_V9FS_SYNTH_FLUSH_FILE) };
P9Req *req, *flush_req;
uint32_t count;
uint8_t should_block;
fs_attach(v9p, NULL, t_alloc);
req = v9fs_twalk(v9p, 0, 1, 1, wnames, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rwalk(req, NULL, NULL);
req = v9fs_tlopen(v9p, 1, O_WRONLY, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rlopen(req, NULL, NULL);
/* This will cause the write request to complete right away, before it
* could be actually cancelled.
*/
should_block = 0;
req = v9fs_twrite(v9p, 1, 0, sizeof(should_block), &should_block, 0);
flush_req = v9fs_tflush(v9p, req->tag, 1);
/* The write request is supposed to complete. The server should
* reply to the write request and the flush request.
*/
v9fs_req_wait_for_reply(req, NULL);
v9fs_rwrite(req, &count);
g_assert_cmpint(count, ==, sizeof(should_block));
v9fs_rflush(flush_req);
g_free(wnames[0]);
}
static void fs_mkdir(void *obj, void *data, QGuestAllocator *t_alloc,
const char *path, const char *cname)
{
QVirtio9P *v9p = obj;
alloc = t_alloc;
char **wnames;
char *const name = g_strdup(cname);
P9Req *req;
const uint32_t fid = genfid();
int nwnames = split(path, "/", &wnames);
req = v9fs_twalk(v9p, 0, fid, nwnames, wnames, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rwalk(req, NULL, NULL);
req = v9fs_tmkdir(v9p, fid, name, 0750, 0, 0);
v9fs_req_wait_for_reply(req, NULL);
v9fs_rmkdir(req, NULL);
g_free(name);
split_free(&wnames);
}
static void fs_readdir_split_128(void *obj, void *data,
QGuestAllocator *t_alloc)
{
fs_readdir_split(obj, data, t_alloc, 128);
}
static void fs_readdir_split_256(void *obj, void *data,
QGuestAllocator *t_alloc)
{
fs_readdir_split(obj, data, t_alloc, 256);
}
static void fs_readdir_split_512(void *obj, void *data,
QGuestAllocator *t_alloc)
{
fs_readdir_split(obj, data, t_alloc, 512);
}
/* tests using the 9pfs 'local' fs driver */
static void fs_create_dir(void *obj, void *data, QGuestAllocator *t_alloc)
{
QVirtio9P *v9p = obj;
struct stat st;
char *root_path = virtio_9p_test_path("");
char *new_dir = virtio_9p_test_path("01");
g_assert(root_path != NULL);
fs_attach(v9p, NULL, t_alloc);
fs_mkdir(v9p, data, t_alloc, "/", "01");
/* check if created directory really exists now ... */
g_assert(stat(new_dir, &st) == 0);
/* ... and is actually a directory */
g_assert((st.st_mode & S_IFMT) == S_IFDIR);
g_free(new_dir);
g_free(root_path);
}
static void *assign_9p_local_driver(GString *cmd_line, void *arg)
{
virtio_9p_assign_local_driver(cmd_line, "security_model=mapped-xattr");
return arg;
}
static void register_virtio_9p_test(void)
{
QOSGraphTestOptions opts = {
};
/* 9pfs test cases using the 'synth' filesystem driver */
qos_add_test("synth/config", "virtio-9p", pci_config, &opts);
qos_add_test("synth/version/basic", "virtio-9p", fs_version, &opts);
qos_add_test("synth/attach/basic", "virtio-9p", fs_attach, &opts);
qos_add_test("synth/walk/basic", "virtio-9p", fs_walk, &opts);
qos_add_test("synth/walk/no_slash", "virtio-9p", fs_walk_no_slash,
&opts);
qos_add_test("synth/walk/dotdot_from_root", "virtio-9p",
fs_walk_dotdot, &opts);
qos_add_test("synth/lopen/basic", "virtio-9p", fs_lopen, &opts);
qos_add_test("synth/write/basic", "virtio-9p", fs_write, &opts);
qos_add_test("synth/flush/success", "virtio-9p", fs_flush_success,
&opts);
qos_add_test("synth/flush/ignored", "virtio-9p", fs_flush_ignored,
&opts);
qos_add_test("synth/readdir/basic", "virtio-9p", fs_readdir, &opts);
qos_add_test("synth/readdir/split_512", "virtio-9p",
fs_readdir_split_512, &opts);
qos_add_test("synth/readdir/split_256", "virtio-9p",
fs_readdir_split_256, &opts);
qos_add_test("synth/readdir/split_128", "virtio-9p",
fs_readdir_split_128, &opts);
/* 9pfs test cases using the 'local' filesystem driver */
opts.before = assign_9p_local_driver;
qos_add_test("local/config", "virtio-9p", pci_config, &opts);
qos_add_test("local/create_dir", "virtio-9p", fs_create_dir, &opts);
}
libqos_init(register_virtio_9p_test);