go-ceph/rados/ioctx.go

890 lines
24 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"
)
// 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 uintptr representation of the IOContext.
func (ioctx *IOContext) Pointer() uintptr {
return uintptr(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)
}
// 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 getRadosError(int(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 getRadosError(int(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 getRadosError(int(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, getRadosError(int(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 getRadosError(int(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 getRadosError(int(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{}, getRadosError(int(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 "", getRadosError(int(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 getRadosError(int(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 getRadosError(int(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{}, getRadosError(int(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, getRadosError(int(ret))
}
// 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 getRadosError(int(ret))
}
// function that lists all the xattrs for an object, since xattrs are
// a k-v pair, this function returns a map of k-v pairs on
// success, error code on failure
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, getRadosError(int(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, getRadosError(int(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 getRadosError(int(ret))
}
// Append the map `pairs` to the omap `oid`
func (ioctx *IOContext) SetOmap(oid string, pairs map[string][]byte) error {
c_oid := C.CString(oid)
defer C.free(unsafe.Pointer(c_oid))
var s C.size_t
var c *C.char
ptrSize := unsafe.Sizeof(c)
c_keys := C.malloc(C.size_t(len(pairs)) * C.size_t(ptrSize))
c_values := C.malloc(C.size_t(len(pairs)) * C.size_t(ptrSize))
c_lengths := C.malloc(C.size_t(len(pairs)) * C.size_t(unsafe.Sizeof(s)))
defer C.free(unsafe.Pointer(c_keys))
defer C.free(unsafe.Pointer(c_values))
defer C.free(unsafe.Pointer(c_lengths))
i := 0
for key, value := range pairs {
// key
c_key_ptr := (**C.char)(unsafe.Pointer(uintptr(c_keys) + uintptr(i)*ptrSize))
*c_key_ptr = C.CString(key)
defer C.free(unsafe.Pointer(*c_key_ptr))
// value and its length
c_value_ptr := (**C.char)(unsafe.Pointer(uintptr(c_values) + uintptr(i)*ptrSize))
var c_length C.size_t
if len(value) > 0 {
*c_value_ptr = (*C.char)(unsafe.Pointer(&value[0]))
c_length = C.size_t(len(value))
} else {
*c_value_ptr = nil
c_length = C.size_t(0)
}
c_length_ptr := (*C.size_t)(unsafe.Pointer(uintptr(c_lengths) + uintptr(i)*ptrSize))
*c_length_ptr = c_length
i++
}
op := C.rados_create_write_op()
C.rados_write_op_omap_set(
op,
(**C.char)(c_keys),
(**C.char)(c_values),
(*C.size_t)(c_lengths),
C.size_t(len(pairs)))
ret := C.rados_write_op_operate(op, ioctx.ioctx, c_oid, nil, 0)
C.rados_release_write_op(op)
return getRadosError(int(ret))
}
// OmapListFunc is the type of the function called for each omap key
// visited by ListOmapValues
type OmapListFunc func(key string, value []byte)
// Iterate on a set of keys and their values from an omap
// `startAfter`: iterate only on the keys after this specified one
// `filterPrefix`: iterate only on the keys beginning with this prefix
// `maxReturn`: iterate no more than `maxReturn` key/value pairs
// `listFn`: the function called at each iteration
func (ioctx *IOContext) ListOmapValues(oid string, startAfter string, filterPrefix string, maxReturn int64, listFn OmapListFunc) error {
c_oid := C.CString(oid)
c_start_after := C.CString(startAfter)
c_filter_prefix := C.CString(filterPrefix)
c_max_return := C.uint64_t(maxReturn)
defer C.free(unsafe.Pointer(c_oid))
defer C.free(unsafe.Pointer(c_start_after))
defer C.free(unsafe.Pointer(c_filter_prefix))
op := C.rados_create_read_op()
var c_iter C.rados_omap_iter_t
var c_prval C.int
C.rados_read_op_omap_get_vals2(
op,
c_start_after,
c_filter_prefix,
c_max_return,
&c_iter,
nil,
&c_prval,
)
ret := C.rados_read_op_operate(op, ioctx.ioctx, c_oid, 0)
if int(ret) != 0 {
return getRadosError(int(ret))
} else if int(c_prval) != 0 {
return RadosError(int(c_prval))
}
for {
var c_key *C.char
var c_val *C.char
var c_len C.size_t
ret = C.rados_omap_get_next(c_iter, &c_key, &c_val, &c_len)
if int(ret) != 0 {
return getRadosError(int(ret))
}
if c_key == nil {
break
}
listFn(C.GoString(c_key), C.GoBytes(unsafe.Pointer(c_val), C.int(c_len)))
}
C.rados_omap_get_end(c_iter)
C.rados_release_read_op(op)
return nil
}
// Fetch a set of keys and their values from an omap and returns then as a map
// `startAfter`: retrieve only the keys after this specified one
// `filterPrefix`: retrieve only the keys beginning with this prefix
// `maxReturn`: retrieve no more than `maxReturn` key/value pairs
func (ioctx *IOContext) GetOmapValues(oid string, startAfter string, filterPrefix string, maxReturn int64) (map[string][]byte, error) {
omap := map[string][]byte{}
err := ioctx.ListOmapValues(
oid, startAfter, filterPrefix, maxReturn,
func(key string, value []byte) {
omap[key] = value
},
)
return omap, err
}
// Fetch all the keys and their values from an omap and returns then as a map
// `startAfter`: retrieve only the keys after this specified one
// `filterPrefix`: retrieve only the keys beginning with this prefix
// `iteratorSize`: internal number of keys to fetch during a read operation
func (ioctx *IOContext) GetAllOmapValues(oid string, startAfter string, filterPrefix string, iteratorSize int64) (map[string][]byte, error) {
omap := map[string][]byte{}
omapSize := 0
for {
err := ioctx.ListOmapValues(
oid, startAfter, filterPrefix, iteratorSize,
func(key string, value []byte) {
omap[key] = value
startAfter = key
},
)
if err != nil {
return omap, err
}
// End of omap
if len(omap) == omapSize {
break
}
omapSize = len(omap)
}
return omap, nil
}
// RmOmapKeys removes the specified `keys` from the omap `oid`
func (ioctx *IOContext) RmOmapKeys(oid string, keys []string) error {
c_oid := C.CString(oid)
defer C.free(unsafe.Pointer(c_oid))
var c *C.char
ptrSize := unsafe.Sizeof(c)
c_keys := C.malloc(C.size_t(len(keys)) * C.size_t(ptrSize))
defer C.free(unsafe.Pointer(c_keys))
i := 0
for _, key := range keys {
c_key_ptr := (**C.char)(unsafe.Pointer(uintptr(c_keys) + uintptr(i)*ptrSize))
*c_key_ptr = C.CString(key)
defer C.free(unsafe.Pointer(*c_key_ptr))
i++
}
op := C.rados_create_write_op()
C.rados_write_op_omap_rm_keys(
op,
(**C.char)(c_keys),
C.size_t(len(keys)))
ret := C.rados_write_op_operate(op, ioctx.ioctx, c_oid, nil, 0)
C.rados_release_write_op(op)
return getRadosError(int(ret))
}
// CleanOmap clears the omap `oid`
func (ioctx *IOContext) CleanOmap(oid string) error {
c_oid := C.CString(oid)
defer C.free(unsafe.Pointer(c_oid))
op := C.rados_create_write_op()
C.rados_write_op_omap_clear(op)
ret := C.rados_write_op_operate(op, ioctx.ioctx, c_oid, nil, 0)
C.rados_release_write_op(op)
return getRadosError(int(ret))
}
type Iter struct {
ctx C.rados_list_ctx_t
err error
entry string
namespace string
}
type IterToken uint32
// Iter returns a Iterator object that can be used to list the object names in the current pool
func (ioctx *IOContext) Iter() (*Iter, error) {
iter := Iter{}
if cerr := C.rados_nobjects_list_open(ioctx.ioctx, &iter.ctx); cerr < 0 {
return nil, getRadosError(int(cerr))
}
return &iter, nil
}
// Token returns a token marking the current position of the iterator. To be used in combination with Iter.Seek()
func (iter *Iter) Token() IterToken {
return IterToken(C.rados_nobjects_list_get_pg_hash_position(iter.ctx))
}
func (iter *Iter) Seek(token IterToken) {
C.rados_nobjects_list_seek(iter.ctx, C.uint32_t(token))
}
// Next retrieves the next object name in the pool/namespace iterator.
// Upon a successful invocation (return value of true), the Value method should
// be used to obtain the name of the retrieved object name. When the iterator is
// exhausted, Next returns false. The Err method should used to verify whether the
// end of the iterator was reached, or the iterator received an error.
//
// Example:
// iter := pool.Iter()
// defer iter.Close()
// for iter.Next() {
// fmt.Printf("%v\n", iter.Value())
// }
// return iter.Err()
//
func (iter *Iter) Next() bool {
var c_entry *C.char
var c_namespace *C.char
if cerr := C.rados_nobjects_list_next(iter.ctx, &c_entry, nil, &c_namespace); cerr < 0 {
iter.err = getRadosError(int(cerr))
return false
}
iter.entry = C.GoString(c_entry)
iter.namespace = C.GoString(c_namespace)
return true
}
// Value returns the current value of the iterator (object name), after a successful call to Next.
func (iter *Iter) Value() string {
if iter.err != nil {
return ""
}
return iter.entry
}
// Namespace returns the namespace associated with the current value of the iterator (object name), after a successful call to Next.
func (iter *Iter) Namespace() string {
if iter.err != nil {
return ""
}
return iter.namespace
}
// Err checks whether the iterator has encountered an error.
func (iter *Iter) Err() error {
if iter.err == RadosErrorNotFound {
return nil
}
return iter.err
}
// Closes the iterator cursor on the server. Be aware that iterators are not closed automatically
// at the end of iteration.
func (iter *Iter) Close() {
C.rados_nobjects_list_close(iter.ctx)
}
// 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), RadosError(int(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), RadosError(int(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), RadosError(int(ret))
}
}
// List 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(int(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), RadosError(int(ret))
}
}