ceph-csi/vendor/github.com/ceph/go-ceph/rados/ioctx.go
Niels de Vos 772d1dfa77 rebase: use go-ceph v0.3.0
v0.3.0 adds support for rbd.FeatureSet that can be used to parse the
features of an RBD image. This will be used in the followup commit that
adds rbdVolume.getImageInfo().

Signed-off-by: Niels de Vos <ndevos@redhat.com>
2020-06-17 09:28:57 +00:00

624 lines
17 KiB
Go

package rados
// #cgo LDFLAGS: -lrados
// #include <errno.h>
// #include <stdlib.h>
// #include <rados/librados.h>
//
// char* nextChunk(char **idx) {
// char *copy;
// copy = strdup(*idx);
// *idx += strlen(*idx) + 1;
// return copy;
// }
//
// #if __APPLE__
// #define ceph_time_t __darwin_time_t
// #define ceph_suseconds_t __darwin_suseconds_t
// #elif __GLIBC__
// #define ceph_time_t __time_t
// #define ceph_suseconds_t __suseconds_t
// #else
// #define ceph_time_t time_t
// #define ceph_suseconds_t suseconds_t
// #endif
import "C"
import (
"syscall"
"time"
"unsafe"
)
// CreateOption is passed to IOContext.Create() and should be one of
// CreateExclusive or CreateIdempotent.
type CreateOption int
const (
// CreateExclusive if used with IOContext.Create() and the object
// already exists, the function will return an error.
CreateExclusive = C.LIBRADOS_CREATE_EXCLUSIVE
// CreateIdempotent if used with IOContext.Create() and the object
// already exists, the function will not return an error.
CreateIdempotent = C.LIBRADOS_CREATE_IDEMPOTENT
)
// PoolStat represents Ceph pool statistics.
type PoolStat struct {
// space used in bytes
Num_bytes uint64
// space used in KB
Num_kb uint64
// number of objects in the pool
Num_objects uint64
// number of clones of objects
Num_object_clones uint64
// num_objects * num_replicas
Num_object_copies uint64
Num_objects_missing_on_primary uint64
// number of objects found on no OSDs
Num_objects_unfound uint64
// number of objects replicated fewer times than they should be
// (but found on at least one OSD)
Num_objects_degraded uint64
Num_rd uint64
Num_rd_kb uint64
Num_wr uint64
Num_wr_kb uint64
}
// ObjectStat represents an object stat information
type ObjectStat struct {
// current length in bytes
Size uint64
// last modification time
ModTime time.Time
}
// LockInfo represents information on a current Ceph lock
type LockInfo struct {
NumLockers int
Exclusive bool
Tag string
Clients []string
Cookies []string
Addrs []string
}
// IOContext represents a context for performing I/O within a pool.
type IOContext struct {
ioctx C.rados_ioctx_t
}
// Pointer returns a pointer reference to an internal structure.
// This function should NOT be used outside of go-ceph itself.
func (ioctx *IOContext) Pointer() unsafe.Pointer {
return unsafe.Pointer(ioctx.ioctx)
}
// SetNamespace sets the namespace for objects within this IO context (pool).
// Setting namespace to a empty or zero length string sets the pool to the default namespace.
func (ioctx *IOContext) SetNamespace(namespace string) {
var c_ns *C.char
if len(namespace) > 0 {
c_ns = C.CString(namespace)
defer C.free(unsafe.Pointer(c_ns))
}
C.rados_ioctx_set_namespace(ioctx.ioctx, c_ns)
}
// Create a new object with key oid.
//
// Implements:
// void rados_write_op_create(rados_write_op_t write_op, int exclusive,
// const char* category)
func (ioctx *IOContext) Create(oid string, exclusive CreateOption) error {
c_oid := C.CString(oid)
defer C.free(unsafe.Pointer(c_oid))
op := C.rados_create_write_op()
C.rados_write_op_create(op, C.int(exclusive), nil)
ret := C.rados_write_op_operate(op, ioctx.ioctx, c_oid, nil, 0)
C.rados_release_write_op(op)
return getError(ret)
}
// Write writes len(data) bytes to the object with key oid starting at byte
// offset offset. It returns an error, if any.
func (ioctx *IOContext) Write(oid string, data []byte, offset uint64) error {
c_oid := C.CString(oid)
defer C.free(unsafe.Pointer(c_oid))
dataPointer := unsafe.Pointer(nil)
if len(data) > 0 {
dataPointer = unsafe.Pointer(&data[0])
}
ret := C.rados_write(ioctx.ioctx, c_oid,
(*C.char)(dataPointer),
(C.size_t)(len(data)),
(C.uint64_t)(offset))
return getError(ret)
}
// WriteFull writes len(data) bytes to the object with key oid.
// The object is filled with the provided data. If the object exists,
// it is atomically truncated and then written. It returns an error, if any.
func (ioctx *IOContext) WriteFull(oid string, data []byte) error {
c_oid := C.CString(oid)
defer C.free(unsafe.Pointer(c_oid))
ret := C.rados_write_full(ioctx.ioctx, c_oid,
(*C.char)(unsafe.Pointer(&data[0])),
(C.size_t)(len(data)))
return getError(ret)
}
// Append appends len(data) bytes to the object with key oid.
// The object is appended with the provided data. If the object exists,
// it is atomically appended to. It returns an error, if any.
func (ioctx *IOContext) Append(oid string, data []byte) error {
c_oid := C.CString(oid)
defer C.free(unsafe.Pointer(c_oid))
ret := C.rados_append(ioctx.ioctx, c_oid,
(*C.char)(unsafe.Pointer(&data[0])),
(C.size_t)(len(data)))
return getError(ret)
}
// Read reads up to len(data) bytes from the object with key oid starting at byte
// offset offset. It returns the number of bytes read and an error, if any.
func (ioctx *IOContext) Read(oid string, data []byte, offset uint64) (int, error) {
c_oid := C.CString(oid)
defer C.free(unsafe.Pointer(c_oid))
var buf *C.char
if len(data) > 0 {
buf = (*C.char)(unsafe.Pointer(&data[0]))
}
ret := C.rados_read(
ioctx.ioctx,
c_oid,
buf,
(C.size_t)(len(data)),
(C.uint64_t)(offset))
if ret >= 0 {
return int(ret), nil
}
return 0, getError(ret)
}
// Delete deletes the object with key oid. It returns an error, if any.
func (ioctx *IOContext) Delete(oid string) error {
c_oid := C.CString(oid)
defer C.free(unsafe.Pointer(c_oid))
return getError(C.rados_remove(ioctx.ioctx, c_oid))
}
// Truncate resizes the object with key oid to size size. If the operation
// enlarges the object, the new area is logically filled with zeroes. If the
// operation shrinks the object, the excess data is removed. It returns an
// error, if any.
func (ioctx *IOContext) Truncate(oid string, size uint64) error {
c_oid := C.CString(oid)
defer C.free(unsafe.Pointer(c_oid))
return getError(C.rados_trunc(ioctx.ioctx, c_oid, (C.uint64_t)(size)))
}
// Destroy informs librados that the I/O context is no longer in use.
// Resources associated with the context may not be freed immediately, and the
// context should not be used again after calling this method.
func (ioctx *IOContext) Destroy() {
C.rados_ioctx_destroy(ioctx.ioctx)
}
// GetPoolStats returns a set of statistics about the pool associated with this I/O
// context.
//
// Implements:
// int rados_ioctx_pool_stat(rados_ioctx_t io,
// struct rados_pool_stat_t *stats);
func (ioctx *IOContext) GetPoolStats() (stat PoolStat, err error) {
c_stat := C.struct_rados_pool_stat_t{}
ret := C.rados_ioctx_pool_stat(ioctx.ioctx, &c_stat)
if ret < 0 {
return PoolStat{}, getError(ret)
}
return PoolStat{
Num_bytes: uint64(c_stat.num_bytes),
Num_kb: uint64(c_stat.num_kb),
Num_objects: uint64(c_stat.num_objects),
Num_object_clones: uint64(c_stat.num_object_clones),
Num_object_copies: uint64(c_stat.num_object_copies),
Num_objects_missing_on_primary: uint64(c_stat.num_objects_missing_on_primary),
Num_objects_unfound: uint64(c_stat.num_objects_unfound),
Num_objects_degraded: uint64(c_stat.num_objects_degraded),
Num_rd: uint64(c_stat.num_rd),
Num_rd_kb: uint64(c_stat.num_rd_kb),
Num_wr: uint64(c_stat.num_wr),
Num_wr_kb: uint64(c_stat.num_wr_kb),
}, nil
}
// GetPoolName returns the name of the pool associated with the I/O context.
func (ioctx *IOContext) GetPoolName() (name string, err error) {
buf := make([]byte, 128)
for {
ret := C.rados_ioctx_get_pool_name(ioctx.ioctx,
(*C.char)(unsafe.Pointer(&buf[0])), C.unsigned(len(buf)))
if ret == -C.ERANGE {
buf = make([]byte, len(buf)*2)
continue
} else if ret < 0 {
return "", getError(ret)
}
name = C.GoStringN((*C.char)(unsafe.Pointer(&buf[0])), ret)
return name, nil
}
}
// ObjectListFunc is the type of the function called for each object visited
// by ListObjects.
type ObjectListFunc func(oid string)
// ListObjects lists all of the objects in the pool associated with the I/O
// context, and called the provided listFn function for each object, passing
// to the function the name of the object. Call SetNamespace with
// RadosAllNamespaces before calling this function to return objects from all
// namespaces
func (ioctx *IOContext) ListObjects(listFn ObjectListFunc) error {
var ctx C.rados_list_ctx_t
ret := C.rados_nobjects_list_open(ioctx.ioctx, &ctx)
if ret < 0 {
return getError(ret)
}
defer func() { C.rados_nobjects_list_close(ctx) }()
for {
var c_entry *C.char
ret := C.rados_nobjects_list_next(ctx, &c_entry, nil, nil)
if ret == -C.ENOENT {
return nil
} else if ret < 0 {
return getError(ret)
}
listFn(C.GoString(c_entry))
}
}
// Stat returns the size of the object and its last modification time
func (ioctx *IOContext) Stat(object string) (stat ObjectStat, err error) {
var c_psize C.uint64_t
var c_pmtime C.time_t
c_object := C.CString(object)
defer C.free(unsafe.Pointer(c_object))
ret := C.rados_stat(
ioctx.ioctx,
c_object,
&c_psize,
&c_pmtime)
if ret < 0 {
return ObjectStat{}, getError(ret)
}
return ObjectStat{
Size: uint64(c_psize),
ModTime: time.Unix(int64(c_pmtime), 0),
}, nil
}
// GetXattr gets an xattr with key `name`, it returns the length of
// the key read or an error if not successful
func (ioctx *IOContext) GetXattr(object string, name string, data []byte) (int, error) {
c_object := C.CString(object)
c_name := C.CString(name)
defer C.free(unsafe.Pointer(c_object))
defer C.free(unsafe.Pointer(c_name))
ret := C.rados_getxattr(
ioctx.ioctx,
c_object,
c_name,
(*C.char)(unsafe.Pointer(&data[0])),
(C.size_t)(len(data)))
if ret >= 0 {
return int(ret), nil
}
return 0, getError(ret)
}
// SetXattr sets an xattr for an object with key `name` with value as `data`
func (ioctx *IOContext) SetXattr(object string, name string, data []byte) error {
c_object := C.CString(object)
c_name := C.CString(name)
defer C.free(unsafe.Pointer(c_object))
defer C.free(unsafe.Pointer(c_name))
ret := C.rados_setxattr(
ioctx.ioctx,
c_object,
c_name,
(*C.char)(unsafe.Pointer(&data[0])),
(C.size_t)(len(data)))
return getError(ret)
}
// ListXattrs lists all the xattrs for an object. The xattrs are returned as a
// mapping of string keys and byte-slice values.
func (ioctx *IOContext) ListXattrs(oid string) (map[string][]byte, error) {
c_oid := C.CString(oid)
defer C.free(unsafe.Pointer(c_oid))
var it C.rados_xattrs_iter_t
ret := C.rados_getxattrs(ioctx.ioctx, c_oid, &it)
if ret < 0 {
return nil, getError(ret)
}
defer func() { C.rados_getxattrs_end(it) }()
m := make(map[string][]byte)
for {
var c_name, c_val *C.char
var c_len C.size_t
defer C.free(unsafe.Pointer(c_name))
defer C.free(unsafe.Pointer(c_val))
ret := C.rados_getxattrs_next(it, &c_name, &c_val, &c_len)
if ret < 0 {
return nil, getError(ret)
}
// rados api returns a null name,val & 0-length upon
// end of iteration
if c_name == nil {
return m, nil // stop iteration
}
m[C.GoString(c_name)] = C.GoBytes(unsafe.Pointer(c_val), (C.int)(c_len))
}
}
// RmXattr removes an xattr with key `name` from object `oid`
func (ioctx *IOContext) RmXattr(oid string, name string) error {
c_oid := C.CString(oid)
c_name := C.CString(name)
defer C.free(unsafe.Pointer(c_oid))
defer C.free(unsafe.Pointer(c_name))
ret := C.rados_rmxattr(
ioctx.ioctx,
c_oid,
c_name)
return getError(ret)
}
// LockExclusive takes an exclusive lock on an object.
func (ioctx *IOContext) LockExclusive(oid, name, cookie, desc string, duration time.Duration, flags *byte) (int, error) {
c_oid := C.CString(oid)
c_name := C.CString(name)
c_cookie := C.CString(cookie)
c_desc := C.CString(desc)
var c_duration C.struct_timeval
if duration != 0 {
tv := syscall.NsecToTimeval(duration.Nanoseconds())
c_duration = C.struct_timeval{tv_sec: C.ceph_time_t(tv.Sec), tv_usec: C.ceph_suseconds_t(tv.Usec)}
}
var c_flags C.uint8_t
if flags != nil {
c_flags = C.uint8_t(*flags)
}
defer C.free(unsafe.Pointer(c_oid))
defer C.free(unsafe.Pointer(c_name))
defer C.free(unsafe.Pointer(c_cookie))
defer C.free(unsafe.Pointer(c_desc))
ret := C.rados_lock_exclusive(
ioctx.ioctx,
c_oid,
c_name,
c_cookie,
c_desc,
&c_duration,
c_flags)
// 0 on success, negative error code on failure
// -EBUSY if the lock is already held by another (client, cookie) pair
// -EEXIST if the lock is already held by the same (client, cookie) pair
switch ret {
case 0:
return int(ret), nil
case -C.EBUSY:
return int(ret), nil
case -C.EEXIST:
return int(ret), nil
default:
return int(ret), getError(ret)
}
}
// LockShared takes a shared lock on an object.
func (ioctx *IOContext) LockShared(oid, name, cookie, tag, desc string, duration time.Duration, flags *byte) (int, error) {
c_oid := C.CString(oid)
c_name := C.CString(name)
c_cookie := C.CString(cookie)
c_tag := C.CString(tag)
c_desc := C.CString(desc)
var c_duration C.struct_timeval
if duration != 0 {
tv := syscall.NsecToTimeval(duration.Nanoseconds())
c_duration = C.struct_timeval{tv_sec: C.ceph_time_t(tv.Sec), tv_usec: C.ceph_suseconds_t(tv.Usec)}
}
var c_flags C.uint8_t
if flags != nil {
c_flags = C.uint8_t(*flags)
}
defer C.free(unsafe.Pointer(c_oid))
defer C.free(unsafe.Pointer(c_name))
defer C.free(unsafe.Pointer(c_cookie))
defer C.free(unsafe.Pointer(c_tag))
defer C.free(unsafe.Pointer(c_desc))
ret := C.rados_lock_shared(
ioctx.ioctx,
c_oid,
c_name,
c_cookie,
c_tag,
c_desc,
&c_duration,
c_flags)
// 0 on success, negative error code on failure
// -EBUSY if the lock is already held by another (client, cookie) pair
// -EEXIST if the lock is already held by the same (client, cookie) pair
switch ret {
case 0:
return int(ret), nil
case -C.EBUSY:
return int(ret), nil
case -C.EEXIST:
return int(ret), nil
default:
return int(ret), getError(ret)
}
}
// Unlock releases a shared or exclusive lock on an object.
func (ioctx *IOContext) Unlock(oid, name, cookie string) (int, error) {
c_oid := C.CString(oid)
c_name := C.CString(name)
c_cookie := C.CString(cookie)
defer C.free(unsafe.Pointer(c_oid))
defer C.free(unsafe.Pointer(c_name))
defer C.free(unsafe.Pointer(c_cookie))
// 0 on success, negative error code on failure
// -ENOENT if the lock is not held by the specified (client, cookie) pair
ret := C.rados_unlock(
ioctx.ioctx,
c_oid,
c_name,
c_cookie)
switch ret {
case 0:
return int(ret), nil
case -C.ENOENT:
return int(ret), nil
default:
return int(ret), getError(ret)
}
}
// ListLockers lists clients that have locked the named object lock and
// information about the lock.
// The number of bytes required in each buffer is put in the corresponding size
// out parameter. If any of the provided buffers are too short, -ERANGE is
// returned after these sizes are filled in.
func (ioctx *IOContext) ListLockers(oid, name string) (*LockInfo, error) {
c_oid := C.CString(oid)
c_name := C.CString(name)
c_tag := (*C.char)(C.malloc(C.size_t(1024)))
c_clients := (*C.char)(C.malloc(C.size_t(1024)))
c_cookies := (*C.char)(C.malloc(C.size_t(1024)))
c_addrs := (*C.char)(C.malloc(C.size_t(1024)))
var c_exclusive C.int
c_tag_len := C.size_t(1024)
c_clients_len := C.size_t(1024)
c_cookies_len := C.size_t(1024)
c_addrs_len := C.size_t(1024)
defer C.free(unsafe.Pointer(c_oid))
defer C.free(unsafe.Pointer(c_name))
defer C.free(unsafe.Pointer(c_tag))
defer C.free(unsafe.Pointer(c_clients))
defer C.free(unsafe.Pointer(c_cookies))
defer C.free(unsafe.Pointer(c_addrs))
ret := C.rados_list_lockers(
ioctx.ioctx,
c_oid,
c_name,
&c_exclusive,
c_tag,
&c_tag_len,
c_clients,
&c_clients_len,
c_cookies,
&c_cookies_len,
c_addrs,
&c_addrs_len)
splitCString := func(items *C.char, itemsLen C.size_t) []string {
currLen := 0
clients := []string{}
for currLen < int(itemsLen) {
client := C.GoString(C.nextChunk(&items))
clients = append(clients, client)
currLen += len(client) + 1
}
return clients
}
if ret < 0 {
return nil, RadosError(ret)
}
return &LockInfo{int(ret), c_exclusive == 1, C.GoString(c_tag), splitCString(c_clients, c_clients_len), splitCString(c_cookies, c_cookies_len), splitCString(c_addrs, c_addrs_len)}, nil
}
// BreakLock releases a shared or exclusive lock on an object, which was taken by the specified client.
func (ioctx *IOContext) BreakLock(oid, name, client, cookie string) (int, error) {
c_oid := C.CString(oid)
c_name := C.CString(name)
c_client := C.CString(client)
c_cookie := C.CString(cookie)
defer C.free(unsafe.Pointer(c_oid))
defer C.free(unsafe.Pointer(c_name))
defer C.free(unsafe.Pointer(c_client))
defer C.free(unsafe.Pointer(c_cookie))
// 0 on success, negative error code on failure
// -ENOENT if the lock is not held by the specified (client, cookie) pair
// -EINVAL if the client cannot be parsed
ret := C.rados_break_lock(
ioctx.ioctx,
c_oid,
c_name,
c_client,
c_cookie)
switch ret {
case 0:
return int(ret), nil
case -C.ENOENT:
return int(ret), nil
case -C.EINVAL: // -EINVAL
return int(ret), nil
default:
return int(ret), getError(ret)
}
}