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qemu-patch-raspberry4/tests/qtest/virtio-9p-test.c
Christian Schoenebeck 4829469fd9 tests/virtio-9p: added readdir test 
The first readdir test simply checks the amount of directory
entries returned by 9pfs server, according to the created amount
of virtual files on 9pfs synth driver side. Then the subsequent
readdir test also checks whether all directory entries have the
expected file names (as created on 9pfs synth driver side),
ignoring their precise order in result list though.

Signed-off-by: Christian Schoenebeck <qemu_oss@crudebyte.com>
Message-Id: <e0b4402722a877178f8fb6a8ad7b64bb20150613.1579567020.git.qemu_oss@crudebyte.com>
Reviewed-by: Greg Kurz <groug@kaod.org>
Signed-off-by: Greg Kurz <groug@kaod.org>
2020-02-08 09:29:04 +01:00

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/*
* 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;
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_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;
}
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]);
}
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 register_virtio_9p_test(void)
{
qos_add_test("config", "virtio-9p", pci_config, NULL);
qos_add_test("fs/version/basic", "virtio-9p", fs_version, NULL);
qos_add_test("fs/attach/basic", "virtio-9p", fs_attach, NULL);
qos_add_test("fs/walk/basic", "virtio-9p", fs_walk, NULL);
qos_add_test("fs/walk/no_slash", "virtio-9p", fs_walk_no_slash,
NULL);
qos_add_test("fs/walk/dotdot_from_root", "virtio-9p",
fs_walk_dotdot, NULL);
qos_add_test("fs/lopen/basic", "virtio-9p", fs_lopen, NULL);
qos_add_test("fs/write/basic", "virtio-9p", fs_write, NULL);
qos_add_test("fs/flush/success", "virtio-9p", fs_flush_success,
NULL);
qos_add_test("fs/flush/ignored", "virtio-9p", fs_flush_ignored,
NULL);
qos_add_test("fs/readdir/basic", "virtio-9p", fs_readdir, NULL);
}
libqos_init(register_virtio_9p_test);
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