Table of Contents

1) Introduction

In July 2024, the upstream Screen maintainer asked us if we could have a look at the current Screen code base. We treated this request with lower priority, since we already had a cursory look at Screen a few years earlier, without finding any problems. When we actually found time to look into it again, we were surprised to find a local root exploit in the Screen 5.0.0 major version update affecting distributions that ship it as setuid-root (Arch Linux and NetBSD). We also found a number of additional, less severe issues that partly also affect older Screen versions still found in the majority of distributions.

We offer two sets of patches for the issues described in this report, one for screen-4.9.1 and another for screen-5.0.0. These patch sets apply against the screen-4.9.1 and screen-5.0.0 release tarballs, respectively. Due to difficulties in the communication with upstream we do not currently have detailed information about bugfixes and releases published on their end.

The next section provides an overview of the Screen configurations and versions found on common Linux and UNIX distributions. Section 3) discusses each security issue we discovered in detail. Section 4) takes a look at possible further issues in Screen’s setuid-root implementation. Section 5) gives general recommendations for the improvement of Screen’s security posture. Section 6) points out problems we encountered during the coordinated disclosure process for these issues. Section 7) provides an affectedness matrix which gives a quick overview of the situation on various Linux and UNIX systems.

2) Overview of Screen Configurations and Versions

In August 2024 a version 5.0.0 major release of Screen was published by upstream. By now Arch Linux, Fedora 42 and NetBSD 10.1 ship this new version of Screen. A lot of refactoring changes made their way into this Screen release that are in some cases dating back more than ten years. Some of the issues discussed in this report have only been introduced in the 5.0.0 release of Screen, while others also affect Screen 4.9.1 (and older), which is still the version found in the majority of Linux and UNIX distributions at the time of writing.

Any source code references in this report are based on the upstream 5.0.0 release tag, unless noted otherwise. Affectedness information is provided for both the current 5.0.0 release and the more widespread 4.9.1 Screen release for each vulnerability discussed below.

NOTE: At the time of writing we often experienced HTTP 502 “Bad Gateway” errors trying to access Screen’s Git web front end. Retrying a few seconds later usually resolved the error.

About the Screen Multi-User Mode

Screen offers a multi-user mode which allows to attach to Screen sessions owned by other users in the system (given the proper credentials). These multi-user features are only available when Screen is installed with the setuid-root bit set. This configuration of Screen results in highly increased attack surface, because of the complex Screen code that runs with root privileges in this case.

A Screen multi-user session is identified by its name, which needs to have a <user>/ prefix. The following command line would create such a session:

user1$ screen -S user1/my-multi-user-session

To manage access to a multi-user session, Screen maintains access control lists (acls) that can be configured in Screen’s configuration file (~/.screenrc), or by sending commands to a running Screen session (see screen(1) man page). These acls are based on the account names of other users and can optionally be protected by a password. Access can be restricted to “read-only”, a mode in which no input can be passed to the terminal.

Of the systems we looked into, only Arch Linux, FreeBSD and NetBSD install Screen with the setuid-root bit set. On Gentoo Linux the setuid-root bit is optionally assigned if the “multiuser” USE flag is set. Some distributions install Screen with a setgid bit assigned to let it run with specific group credentials. This is the case on Gentoo Linux by default, which installs Screen as setgid-utmp, allowing Screen to create login records in the system-wide utmp database. Fedora Linux installs Screen as setgid-screen, which allows Screen to place sockets into a system-wide directory in /run/screen.

3) Security Issues

3.a) Local Root Exploit via logfile_reopen() (CVE-2025-23395)

This issue affects Screen 5.0.0 when it runs with setuid-root privileges. The function logfile_reopen() does not drop privileges while operating on a user supplied path. This allows unprivileged users to create files in arbitrary locations with root ownership, the invoking user’s (real) group ownership and file mode 0644. All data written to the Screen PTY will be logged into this file. Also already existing files can be abused for logging in this manner: the data will be appended to the file in question, but the file mode and ownership will be left unchanged.

Screen correctly drops privileges when it initially opens the logfile. The privilege escalation becomes possible as soon as Screen believes it is necessary to reopen the logfile. Screen checks this by calling stolen_logfile() before writing to the file. The call to logfile_reopen() happens when the link count of the originally opened logfile drops to zero, or if it unexpectedly changes in size. This condition can be triggered at will on the end of the unprivileged user.

This is a reproducer which shows how to achieve a basic local root exploit on an affected system:

# create a Screen session using a custom logfile path
(shell1) user$ screen -Logfile $HOME/screen.log
# enter the key combination to enable logging to the configured path
(screen) user$ <ctrl-a> H

# in another shell remove the logfile that Screen just created and
# replace it by a symlink to a privileged location
(shell2) user$ rm $HOME/screen.log; ln -s /etc/profile.d/exploit.sh \
    $HOME/screen.log

# back in the Screen session, echo an exploit command which will be logged to
# the now redirected logfile.
#
# This needs to be done via `echo` for adding a leading newline to prevent the
# bash prompt from breaking the exploit. Similarly the trailing semicolon
# is necessary to prevent following control characters from becoming part of
# the shell command.
(screen) user$ echo -e "\nchown $USER /root;"

# now perform a new login as root and watch the exploit being executed.
# you will likely see a range of shell errors during login as well.
root# ls -lhd /root
drwxr-x--- 5 user root 4.0K Dec 30  2020 .

This is just one naive approach to achieve a local root exploit, which is not very well hidden (because of strange error messages) and requires the actual root user to login to trigger it. There are likely many other ways to exploit this, however, for example by writing new configuration files for tools like sudo, or by appending code to privileged shell scripts found in /usr/bin and similar locations.

Bugfix

The problem was introduced via an old commit 441bca708bd, which has only now become part of the 5.0.0 release. In this commit the lf_secreopen() function was removed, which was considered unneeded.

Patch 0001 in screen-5.0.0-patches.tar.gz addresses the issue by reintroducing the secure file handling during logfile reopen.

Affected Distributions

Arch Linux

Arch Linux is fully affected by this issue, since it ships the version 5.0.0 release and assigns the setuid-root bit. Screen is not installed by default on Arch, however.

Fedora Linux

The affected 5.0.0 version is only found in the recently released Fedora 42. Screen runs with setgid-screen credentials there, to be able to write in the /run/screen directory. A private directory with mode 0700 is created in there for each user that runs a Screen multi-user session. Due to this, the exploit will not allow to write in other users’ session directories, it will only be possible to create files directly in /run/screen. The only attack vector we can imagine here is to cause a local DoS scenario by claiming the names of other users’ session directories, should they not yet exist. Another attack vector could be to try and fill up the free disk space of the /run file system (a TMPFS) to break other system services.

Gentoo Linux

Gentoo Linux is not affected in its stable Screen ebuild, which is still based on Screen version 4.9.1.

When using Gentoo’s unstable ‘app-misc/screen-9999’ ebuild, then the affected version 5.0.0 will be installed, however. If the “multiuser” USE flag is also set, then the setuid-root bit will be applied, resulting in a fully vulnerable Screen.

Without this USE flag, Screen runs as setgid-utmp on Gentoo Linux, which allows to use this exploit to overwrite the /var/log/wtmp database. This makes it possible to violate the integrity of the database or even to craft login entries which could adversely influence other privileged programs in the system that rely on this information.

FreeBSD

FreeBSD still uses version 4.9.1. If Screen were to be upgraded to 5.0.0 then FreeBSD would be affected as well, since Screen is installed as setuid-root by default.

NetBSD

On NetBSD the affected Screen 5.0.0 version can be installed and it will by default run with setuid-root privileges. This makes it fully affected by the issue.

3.b) TTY Hijacking while Attaching to a Multi-User Session (CVE-2025-46802)

This issue is found in the Attach() function when the multiattach flag is set (i.e. Screen attempts to attach to a multi-user session). The function performs a chmod() of the current TTY to mode 0666. The path to the current TTY is stored in the attach_tty string:

if ((how == MSG_ATTACH || how == MSG_CONT) && multiattach) {
    /* snip */
    if (chmod(attach_tty, 0666))
        Panic(errno, "chmod %s", attach_tty);
    tty_oldmode = tty_mode;
}

Fortunately the TTY path which is calculated within Screen is sufficiently probed for correctness. In particular, isatty() needs to be true for FD 0 (which is used for determining the TTY path) and the resulting path needs to reside in /dev. Otherwise this chmod() would have led to another local root exploit.

The original TTY mode is restored towards the end of the function in line 284. We are not completely sure about the purpose of this temporary permission change, maybe it is supposed to allow the Screen daemon of the target session (which might have different credentials) to access the client’s TTY for the purposes of the attach procedure.

The issue with this temporary TTY mode change is that it introduces a race condition allowing any other user in the system to open the caller’s TTY for reading and writing for a short period of time. We made some simple tests based on Linux’s inotify API, and we managed to open affected TTYs every second or third attempt using a simple Python script this way.

The impact of this issue is that an attacker can intercept data typed into the TTY and also inject data into it. An attacker could attempt to mislead the owner of the TTY into entering a password, or gain other sensitive information. Also, control sequences can be injected into the affected TTY which adds further possibilities to confuse the victim or to exploit issues in an involved terminal emulator.

There also exist return paths in the Attach() function where the original mode is never restored again. This happens in line 160, for instance, where the process explicitly exits if the target session is not found and the “quiet” command line argument has been set. A simple reproducer of this aspect is as follows:

    # inspect the current TTY permissions, which are safe
    user$ ls -l `tty`
    crw--w---- 1 user tty 136, 1 Feb  5 12:18 /dev/pts/1
    # attempt to attach to some non-existing session of the root user.
    # note that this only works if the target user's session directory (e.g.
    # in $HOME/.screen) already exists, otherwise the logic terminates early
    # and the `chmod()` does not happen.
    user$ screen -r -S root/some-session -q
    # observe the now unsafe TTY permissions
    user$ ls -l `tty`
    crw-rw-rw- 1 user tty 136, 1 Feb  5 12:19 /dev/pts/1

The Panic() function, which is mostly used in Attach() to stop process execution, correctly restores the old TTY mode. Only code paths that use return or eexit() suffer from this missing TTY mode restore.

Bugfix

We assume that the problematic chmod() calls are most likely only remnants of past times, when this insecure approach was used to grant the target Screen session access to the new client’s PTY. These days Screen passes the PTY file descriptor securely via the UNIX domain socket to the target session.

Thus to fix this, the temporary chmod() to mode 666 can be dropped. This is what is done in patch 0001 in screen-4.9.1.tar.gz and patch 0004 in screen-5.0.0.tar.gz.

Shortly before the publication of this report it was pointed out to us that this patch likely breaks some reattach use cases in Screen. We can confirm this problem, but at the same time found out that this specific use case was obviously already broken before, even in Screen 4.9.1. For this reason we decided not to move the publication date again or to adjust this patch in a hurry with uncertain results. The patch still fixes the security issue and upstream can now fix this regression, that already seems to have existed earlier, in the open.

Affected Distributions

Unlike the previous issue, this one is not limited to the current 5.0.0 release. The observed behaviour has been present in Screen versions since at least the year 2005. All Linux distributions and BSDs we checked suffer from this, if they provide multi-user support in Screen by installing it setuid-root.

This issue theoretically also affects Screen if it is not installed setuid-root, because the caller always has permission to modify the mode of its own TTY. Screen refuses to continue the operation, however, if the target session is not owned by the caller and no root privileges are available. The problematic code still triggers when a user attempts for some reason to join a multi-user session owned by itself. An example invocation that leads to this would be screen -r -S $USER/some-session -q. Systems that are affected by this lighter variant of the issue are marked as partly affected in section 7).

3.c) Screen by Default Creates World Writable PTYs (CVE-2025-46803)

In Screen version 5.0.0 the default mode of pseudo terminals (PTYs) allocated by Screen was changed from 0620 to 0622, thereby allowing anyone to write to any Screen PTYs in the system. Security-wise this results in some of the issues that have been outlined in issue 3.b), without the information leak aspects, however.

The history of the default PTY mode in Screen is rather complex. Let’s have a look at the situation in version 4.9.1 (and a lot of older versions):

  • There is a 0622 default mode in the code in process.c line 207. This is only a fallback that should not become active unless the code is compiled in unusual ways.
  • A default mode of 0620 is applied in configure.ac line 811, which results in a safe default when compiling Screen using autotools.

  • In acconfig.h line 81 the following is stated:

    define PTYMODE if you do not like the default of 0622, which allows public write to your pty.

    Thus in this version there is an inconsistency between the default mode on autoconf level and the default on source code level, but in the end the (safe) autoconf default wins.

Now let’s look at the situation in Screen version 5.0.0:

  • The configure.ac file was rewritten from scratch in commit df1c012227. This change drops the 0620 default mode on autoconf level.
  • In a follow-up commit 78a961188f7 the pty-mode configure switch was reintroduced, this time with default mode 0622.
  • Thus in version 5.0.0 there is no longer a mismatch between the source code level default and the autoconf level default, but the default is now unsafe.

Bugfix

We couldn’t find any Screen release notes for version 5.0.0, except for a few ChangeLog entries. It seems it was not a deliberate decision to change the default PTY Mode to 0622.

Patch 0002 in screen-5.0.0-patches.tar.gz addresses the issue by restoring the safe default PTY mode in the configure.ac script. Note that you will need to run autoreconf to make the change effective.

We recommend to packagers to actively pass the configure switch --with-pty-mode=0620 to make this choice explicit, also on older releases of Screen.

Affected Distributions

Gentoo Linux and Fedora Linux pass an explicit safe --with-pty-mode to Screen’s configure script. For distributions other than the ones listed as affected below, we did not check if they are either doing the same, or if they are relying on the safe default present in older Screen releases.

Arch Linux

On Arch Linux the package build does not pass the --with-pty-mode switch, resulting in the new default being applied, thus making Screen on current Arch Linux vulnerable to this issue.

NetBSD

NetBSD is affected by this issue the same way as Arch Linux is.

3.d) File Existence Tests via Socket Lookup Error Messages (CVE-2025-46804)

This is a minor information leak when running Screen with setuid-root privileges that is found in older Screen versions, as well as in version 5.0.0. The code in screen.c starting at line 849 inspects the resulting SocketPath with root privileges, and provides error messages that allow unprivileged users to deduce information about the path that would otherwise not be available.

An easy way to achieve this is by using the SCREENDIR environment variable. Following is an example that works on current Arch Linux:

# this can be used to test whether /root/.lesshst exists and is a regular file
user$ SCREENDIR=/root/.lesshst screen
/root/.lesshst is not a directory.

# this allows to deduce that the directory /root/.cache exists
user$ SCREENDIR=/root/.cache screen
bind (/root/.cache/1426.pts-0.mgarch): Permission denied

# this tells us that the path /root/test does not exist
user $ SCREENDIR=/root/test screen
Cannot access /root/test: No such file or directory

Bugfix

Patch 0002 in screen-4.9.1.tar.gz and patch 0005 in screen-5.0.0.tar.gz address the problem by only outputting generic error messages when Screen is installed setuid-root and when the target path is not controlled by the real UID of the process.

Affected Distributions

All distributions we considered are affected.

3.e) Race Conditions when Sending Signals (CVE-2025-46805)

In socket.c lines 646 and 882 time-of-check/time-of-use (TOCTOU) race conditions exist with regards to sending signals to user supplied PIDs in setuid-root context.

The CheckPid() function drops privileges to the real user ID and tests whether the kernel allows to send a signal to the target PID using these credentials. The actual signal is sent later via Kill(), potentially using full root privileges. By this time, the PID that was previously checked could have been replaced by a different, privileged process. It might also be possible to trick the (privileged) Screen daemon process into sending signals to itself, since a process is always allowed to send signals to itself.

Currently this should only allow to send SIGCONT and SIGHUP signals, thus the impact is likely only in the area of a local denial of service or a minor integrity violation.

The issue affects both Screen version 5.0.0 and older version 4 releases, when Screen is installed setuid-root. This issue results from an incomplete fix for CVE-2023-24626: before this incomplete fix, the signals in question could be sent to arbitrary processes even without winning a race condition.

Bugfix

Patch 0003 in screen-4.9.1.tar.gz and patch 0006 in screen-5.0.0.tar.gz address the problem by sending the actual signal with real UID privileges, just like CheckPid() does.

Affected Distributions

All distributions we considered are affected.

3.f) Bad strncpy() Use Leads to Crashes when Sending Commands

We believe this is a non-security issue, but one that still should be fixed with priority. The issue is only found in Screen version 5.0.0.

In commit 0dc67256 a number of strcpy() calls have been replaced by strncpy(). The author obviously was not aware of the unfortunate semantics that strncpy() has. This function is not intended for safe string handling, but to maintain zero padded buffers of fixed length. For this reason, strncpy() does not stop writing data to the destination buffer when the first \0 byte is encountered, but it writes out zeroes until the buffer is completely filled.

Apart from leading to bad performance, this also triggers a bug in attacher.c line 465. The following change has been applied there:

-      strcpy(p, *av);
+      strncpy(p, *av, MAXPATHLEN);
       p += len;

These lines are part of the following for loop, which processes command line parameters to send them to a running Screen session.

for (; *av && n < MAXARGS - 1; ++av, ++n) {
        size_t len;
        len = strlen(*av) + 1;
        if (p + len >= m.m.command.cmd + ARRAY_SIZE(m.m.command.cmd) - 1)
                break;
        strncpy(p, *av, MAXPATHLEN);
        p += len;
}

The call to strncpy() always passes MAXPATHLEN bytes as destination buffer size. This is correct for the first iteration of the for loop, when p points to the beginning of the struct Message.command.cmd buffer declared in screen.h line 148. It is no longer correct for following iterations of the for loop, however, when p is incremented by len. This means future strncpy() calls will write an excess amount of \0 bytes beyond the end of the buffer.

The result of this can be observed on current Arch Linux when passing more than one command argument to a running Screen instance:

# create a new screen session
user$ screen -S myinstance

# and detach from it again
(screen) user$ <Ctrl A> d

# now try to send a command to the running session
user$ screen -S myinstance -X blankerprg /home/$USER/blanker
*** buffer overflow detected ***: terminated
Aborted (core dumped)

The two command arguments lead to two iterations in the for loop described above; the second iteration will trigger the buffer overflow detection. The visible error only occurs when Screen is compiled with the _FORTIFY_SOURCE feature enabled. Otherwise no errors are seen, not even when compiling with -fsanitize=address, likely because after the end of the target buffer another long buffer char message[MAXPATHLEN * 2] follows (thus only application payload data is overwritten).

This issue allows the caller to overwrite MAXPATHLEN bytes of memory following the cmd buffer with zeroes, which can cause integrity violation in Screen, particularly when it runs setuid-root. Since an equally sized buffer writeback[MAXPATHLEN] follows in memory, there should be no possibilities to exploit this issue to the advantage of an attacker, however.

To fix this, MAXPATHLEN needs to be replaced by the actually remaining amount of bytes in p. Furthermore ideally all strncpy() calls should be replaced by snprintf(target, target_size, "%s", source) to avoid the unintended effect of zero padding the target buffer.

We wondered how this issue could be present in Screen 5.0.0 for such a long time without anybody noticing. One part of the explanation likely is that Screen version 5.0.0 is only present in few distributions so far. Another aspect is that perhaps only few users are using this feature to send commands to running Screen sessions. We still found a report from not too long ago on the screen-users mailing list that seems to refer to exactly this issue.

Bugfix

Patch 0003 in screen-5.0.0.tar.gz addresses this problem by changing strncpy() to snprintf() and by properly passing the amount of remaining space in the target buffer.

Affected Distributions

All distributions shipping screen-5.0.0 are affected.

4) Possible Further Issues in Screen’s setuid-root Implementation

While working on the bugfix for issue 3.e), we also noticed that the original (incomplete) bugfix for CVE-2023-24626 introduced a regression to the multi-user mode in Screen when the target session is running as non-root. In this case the target session drops privileges to some UID X and then attempts to send a signal to some UID Y (of the client), which will always fail.

This shows that there are actually three different UIDs to be considered in Screen’s multi-user mode: effective UID 0 to perform privileged operations, the real UID of the user creating the session and the real UID of the user attaching to a session. We don’t believe that the current Screen code takes this properly into account.

This also brought to our attention that Screen multi-user sessions created by root will “drop privileges” to the real UID of the creating user, which will be UID 0, and thus effectively perform no privilege drop at all.

5) General Recommendations

From the changes in Screen 5.0.0 we can see that there have been attempts for a longer time to refactor the code base, which was still written in K&R style C before that. During this refactoring some of the long established security logic has been broken, however, which led to issues 3.a) and 3.c). Before doing further refactoring, some kind of test suite could be helpful to verify various security properties of the implementation. Also anybody who works on this code base obviously should have knowledge about the many dangers that linger in setuid-root binaries.

Even after fixing the issues we identified during our review, there are still many areas left that make us worry as outlined in the previous section. There is also a range of file system operations where security is hanging by a thread.

There is furthermore a broad design issue in Screen: it runs with elevated privileges all the time, and only selectively drops privileges for operations that are considered dangerous. For a robust setuid-root program this should be the other way around: privileges should be dropped by default and only raised for operations that actually require elevated privileges.

To make Screen acceptable for running setuid-root we suggest to implement a design change in this regard and to carefully review each privileged operation that remains for its security. We also suggest to add logic to remove any environment variables except those that are explicitly allowed in the setuid-root context. Other environment variables like PATH should be sanitized to point only to trusted system directories.

Given all this, we don’t recommend to install Screen setuid-root at all at the moment (neither version 5.0.0 nor the older 4.9 versions). An alternative could be to offer the multi-user feature only in an opt-in fashion, e.g. by allowing only members of a trusted group to run a multi-user version of Screen.

6) Problematic Coordinated Disclosure Process and Upstream Status

When we reported these issues to upstream in February 2025, we offered the usual coordinated disclosure process based on our policy. Upstream expressed a lot of interest in keeping the issues private to develop bugfixes before publication. A time frame of one to two months was communicated to us for this purpose. We were not too happy with this long embargo period, but we understand that many upstreams are lacking resources, thus we agreed to these terms.

About a month later some activity ensued on upstream’s end and discussions about bugfixes started. These discussions were not too fruitful, but we still believed that upstream would be able to deal with the issues - given it was upstream itself that asked us to perform a security review for Screen.

No further communication happened, however, until about two weeks before the maximum 90 days embargo period we offer, when we inquired upstream about the current status and pointed out the publication date coming close. We had to find out that upstream did not use the long time period up to this point to work on the bugfixes. Meanwhile further distributions like NetBSD updated to Screen 5.0.0, becoming fully affected by issue 3.a), unaware of the risk.

It was only at this point that we realized that upstream was not sufficiently familiar with the Screen code base, not capable of fully understanding the security issues we reported and that they did not clearly state that they need more help than us only reviewing patches they come up with.

The communication with upstream became increasingly problematic: upstream suddenly wanted to publish bugfixes earlier than we suggested, even though many issues were still unaddressed. We tried to dissuade upstream and quickly involved the distros mailing list to make other distributors aware of the issues. We exceptionally suggested a publication date beyond our maximum 90 days embargo to the list, to accommodate for the chaotic situation that the embargo ended up in.

After some further not very productive attempts to develop patches in cooperation with upstream, we decided to take the matter into our own hands. We developed the missing bugfixes and adjusted and properly documented the patches that had already been drafted by upstream. In doing this, we deduced that a dedicated upstream would likely have been able to complete the coordinated disclosure process within about two weeks.

We are not satisfied with how this coordinated disclosure developed, and we will try to be more attentive to such problematic situations early on in the future. This experience also sheds light on the overall situation of Screen upstream. It looks like it suffers from a lack of manpower and expertise, which is worrying for such a widespread open source utility. We hope this publication can help to draw attention to this and to improve this situation in the future.

7) Affectedness Matrix

System Screen Version Special Privileges Affected by Comment
Arch Linux 5.0.0 setuid-root 3.a, 3.b, 3.c, 3.d, 3.e, 3.f  
Debian 12.10 4.9.0   3.b (partly)  
Ubuntu 24.04.2 4.9.1   3.b (partly)  
Fedora 42 5.0.0 setgid-screen 3.b (partly), 3.f 5.0.0 is only found in the recently released Fedora 42
Gentoo 4.9.1 setgid-utmp (setuid-root if multiuser USE flag is set) 3.b (partly) 5.0.0 is available via the unstable ebuild
openSUSE TW 4.9.1   3.b (partly)  
FreeBSD 14.2 4.9.1 setuid-root 3.b, 3.d, 3.e  
NetBSD 10.1 5.0.0 setuid-root 3.a, 3.b, 3.c, 3.d, 3.e, 3.f (without visible crash) update to 5.0.0 was only released recently
OpenBSD 7.7 4.9.1   3.b (partly)  

8) Timeline

2024-07-01 A review request from upstream was forwarded to us.
2025-01-08 We started working on the review.
2025-02-07 We privately reported the issues to the Screen upstream by email, offering coordinated disclosure.
2025-02-07 Upstream expressed that they will need 1 - 2 months of time to work on the issues, likely requiring most of the 90 days maximum embargo period we offered.
2025-02-11 We created private bugs in the GNU Savannah bug tracker to deal with each finding.
2025-03-11 Some discussions started in the private GNU Savannah bugs about patches for a couple of the findings.
2025-04-29 After nearly a month without visible activity, and the 90 days maximum embargo time approaching we asked upstream for the current status and procedures for publication of the report.
2025-04-30 Upstream started taking up work again, trying to come up with fixes until the end of the 90 day embargo period. We offered advice on the various patches in the private GNU Savannah bugs.
2025-04-30 Following some unclarity in the discussion with upstream regarding CVE assignment, we decided to assign CVEs for the security relevant issues.
2025-04-30 Upstream declared its intention to publish something on the weekend, while bugfixes were still missing. We urged them not to do this. In the light of this we quickly forwarded a draft of this report to the distros mailing list to give other distributors the chance to react to these findings before they go public.
2025-05-05 Although we did not get a clear answer, upstream ended up not publishing one-sidedly. Given the chaotic situation we suggested a publication date of 2025-05-12 to the distros mailing list, which was a few days after the 90 days maximum embargo period we usually offer upstream.
2025-05-07 Further attempts to develop the missing bugfixes in cooperation with upstream seemed futile. We started to develop all necessary patches on our own, some of them based on patches that had already been discussed in the upstream Savannah bugs. We shared the finished and tested patches for screen 4.9.1 and screen 5.0.0 with the distros mailing list and upstream.
2025-05-08 Upstream complained about wrong Author: tags in some of the patches we distributed (we did not receive formally finished patches from upstream, only copy/paste snippets). Thus we adjusted the authorship information for these patches to accommodate for this complaint and shared the updated result with the distros mailing list again.
2025-05-12 Publication of the report happened as planned on our blog and on the oss-security mailing list.

9) References