Short answer yes.
You can read more about it here:
As it is said there, the child process is an exact duplicate of the parent process except
for the following points:
* The child has its own unique process ID, and this PID does not
match the ID of any existing process group (setpgid(2)).
* The child's parent process ID is the same as the parent's process
* The child does not inherit its parent's memory locks (mlock(2),
* Process resource utilizations (getrusage(2)) and CPU time counters
(times(2)) are reset to zero in the child.
* The child's set of pending signals is initially empty
* The child does not inherit semaphore adjustments from its parent
* The child does not inherit process-associated record locks from
its parent (fcntl(2)). (On the other hand, it does inherit
fcntl(2) open file description locks and flock(2) locks from its
* The child does not inherit timers from its parent (setitimer(2),
* The child does not inherit outstanding asynchronous I/O operations
from its parent (aio_read(3), aio_write(3)), nor does it inherit
any asynchronous I/O contexts from its parent (see io_setup(2)).
The process attributes in the preceding list are all specified in
POSIX.1. The parent and child also differ with respect to the
following Linux-specific process attributes:
* The child does not inherit directory change notifications
(dnotify) from its parent (see the description of F_NOTIFY in
* The prctl(2) PR_SET_PDEATHSIG setting is reset so that the child
does not receive a signal when its parent terminates.
* The default timer slack value is set to the parent's current timer
slack value. See the description of PR_SET_TIMERSLACK in
* Memory mappings that have been marked with the madvise(2)
MADV_DONTFORK flag are not inherited across a fork().
* The termination signal of the child is always SIGCHLD (see
* The port access permission bits set by ioperm(2) are not inherited
by the child; the child must turn on any bits that it requires
Note the following further points:
* The child process is created with a single thread—the one that
called fork(). The entire virtual address space of the parent is
replicated in the child, including the states of mutexes,
condition variables, and other pthreads objects; the use of
pthread_atfork(3) may be helpful for dealing with problems that
this can cause.
* After a fork(2) in a multithreaded program, the child can safely
call only async-signal-safe functions (see signal(7)) until such
time as it calls execve(2).
* The child inherits copies of the parent's set of open file
descriptors. Each file descriptor in the child refers to the same
open file description (see open(2)) as the corresponding file
descriptor in the parent. This means that the two file
descriptors share open file status flags, file offset, and signal-
driven I/O attributes (see the description of F_SETOWN and
F_SETSIG in fcntl(2)).
* The child inherits copies of the parent's set of open message
queue descriptors (see mq_overview(7)). Each file descriptor in
the child refers to the same open message queue description as the
corresponding file descriptor in the parent. This means that the
two file descriptors share the same flags (mq_flags).
* The child inherits copies of the parent's set of open directory
streams (see opendir(3)). POSIX.1 says that the corresponding
directory streams in the parent and child may share the directory
stream positioning; on Linux/glibc they do not.