Message ID | 20191209224530.156283-1-zenczykowski@gmail.com |
---|---|
State | Changes Requested |
Delegated to: | David Miller |
Headers | show |
Series | [v2] net: introduce ip_local_unbindable_ports sysctl | expand |
On Mon, 9 Dec 2019 14:45:30 -0800, Maciej Żenczykowski wrote: > Example use cases might be: > - a port being stolen by the nic for remote serial console, remote > power management or some other sort of debugging functionality > (crash collection, gdb, direct access to some other microcontroller > on the nic or motherboard, remote management of the nic itself). This use case makes me a little uncomfortable. Could you elaborate what protocols and products are in need of this functionality? Why can't the NIC just get its own IP like it usually does with NCSI?
> Could you elaborate what protocols and products are in need of this > functionality? The ones I'm aware of are: (a) Google's servers (b) Android on at least some chipsets (Qualcomm at the bare minimum, but I think it's pretty standard a solution) where there's a complex port sharing scheme between the Linux kernel on the Application Processor and the Firmware running on the modem (for ipv4 we only get one ip address from the cellular carrier). It's basically required for things like wifi calling to work. > Why can't the NIC just get its own IP like it usually does with NCSI? Because often these nics are deployed as in place upgrades in environments where there's a limited number of IPs. Say a rack with a /27 ipv4 subnet (2**5 = 32 -> 29 usable ips, since network/broadcast/gateway are burned) and 15+ pre-existing machines. This means there's not enough IPs to assign separate ones for the nics. Renumbering the rack, would imply renumbering the datacenter, etc... And ipv4 - even RFC1918 - has long run out - so even in new deployments there's not enough IPv4 ips to give to nics, and IPv6 isn't yet deployed *everywhere*.
On Tue, 10 Dec 2019 01:02:08 +0100, Maciej Żenczykowski wrote: > > Could you elaborate what protocols and products are in need of this > > functionality? > > The ones I'm aware of are: > (a) Google's servers > (b) Android on at least some chipsets (Qualcomm at the bare minimum, > but I think it's pretty standard a solution) where there's a complex > port sharing scheme between the Linux kernel on the Application > Processor and the Firmware running on the modem (for ipv4 we only get > one ip address from the cellular carrier). It's basically required > for things like wifi calling to work. Okay, that's what I was suspecting. It'd be great if the real motivation for a patch was spelled out in the commit message :/ So some SoCs which run non-vanilla kernels require hacks to steal ports from the networking stack for use by proprietary firmware. I don't see how merging this patch benefits the community. > > Why can't the NIC just get its own IP like it usually does with NCSI? > > Because often these nics are deployed as in place upgrades in > environments where there's a limited number of IPs. > Say a rack with a /27 ipv4 subnet (2**5 = 32 -> 29 usable ips, since > network/broadcast/gateway are burned) and 15+ pre-existing machines. > This means there's not enough IPs to assign separate ones for the nics. > Renumbering the rack, would imply renumbering the datacenter, etc... > And ipv4 - even RFC1918 - has long run out - so even in new > deployments there's not enough IPv4 ips to give to nics, and IPv6 > isn't yet deployed *everywhere*. So the conditions for this are: - in-place upgrade of an existing rack - IPv4 only - the existing servers didn't have NCSI or otherwise IPs for OOB control Unlike the AP one this sounds like a very rare scenario..
> Okay, that's what I was suspecting. It'd be great if the real > motivation for a patch was spelled out in the commit message :/ > > So some SoCs which run non-vanilla kernels require hacks to steal > ports from the networking stack for use by proprietary firmware. > > I don't see how merging this patch benefits the community. > This is just a transparent proxy scenario though. We block the specific ports so that there is no unrelated traffic belonging to host proxied here incorrectly.
> Okay, that's what I was suspecting. It'd be great if the real > motivation for a patch was spelled out in the commit message :/ It is, but the commit message is already extremely long. At some point essays and discussions belong in email and not in the commit message. Here's another use case: A network where firewall policy or network behaviour blocks all traffic using specific ports. I've seen generic firewalls that unconditionally drop all BGP or SMTP port traffic, or all traffic on ports 5060/5061 (regardless of direction) or on 25/53/80/123/443/853/3128/8000/8080/8088/8888 (usually due to some ill guided security policies against sip or open proxies or xxx). If you happen to use port XXXX as your source port your connection just hangs (packets are blackholed). Sure you can argue the network is broken, but in the real world you often can't fix it... Go try and convince your ISP that they should only drop inbound connections to port 8000, but not outgoing connections from port 8000 - you'll go crazy before you find someone who even understands what you're talking about - and even if you find such a person, they'll probably be too busy to change things - and even though it might be a 1 letter change (port -> dport) - it still might take months of testing and rollout before it's fully deployed. I've seen networks where specific ports are automatically classified as super high priority (network control) so you don't want anything using these ports without very good reason (common for BGP for example, or for encap schemes). Or a specific port number being reserved by GUE or other udp encap schemes and thus unsafe to use for generic traffic (because the network or even the kernel itself might for example auto decapsulate it [via tc ebpf for example], or parse the interior of the packet for flowhashing purposes...). [I'll take this opportunity to point out that due to poor flow hashing behaviour GRE is basically unusable at scale (not to mention poorly extensible), and thus GUE and other UDP encap schemes are taking over] Or you might want to forward udp port 4500 from your external IP to a dedicated ipsec box or some hardware offload engine... etc. > So some SoCs which run non-vanilla kernels require hacks to steal > ports from the networking stack for use by proprietary firmware. > I don't see how merging this patch benefits the community. I think you're failing to account for the fact that the majority of Linux users are Android users - there's around 2.5 billion Android phones in the wild... - but perhaps you don't consider your users (or Android?) to be part of your community? btw. Chrome OS is also Linux based (and if a quick google search is to be believed, about 1/7th of the linux desktop/laptop share), but since it supports running Android apps, it needs to have all Android specific generic kernel changes... The reason Android runs non-vanilla kernels is *because* patches like this - that make Linux work in the real world - are missing from vanilla Linux (I can think of a few other networking patches off the top of my head where we've been unable to upstream them for no particularly good reason). > So the conditions for this are: > - in-place upgrade of an existing rack No that's just an example. That said in place upgrades aren't particularly rare. > - IPv4 only Believe it or not most embedded gear is still very much ipv4 only, as much as I hate that - I've been working on ipv6 deployment for over a decade now, and the amount of stuff that's IPv4-only is still staggering. > Unlike the AP one this sounds like a very rare scenario.. And yet I have 2 ports for 2 different pieces of hardware that I need to block this way (and a third one for GUE and a fourth one for some ipsec-like crypto transport).
On Tue, 10 Dec 2019 07:00:29 +0000, subashab@codeaurora.org wrote: > > Okay, that's what I was suspecting. It'd be great if the real > > motivation for a patch was spelled out in the commit message :/ > > > > So some SoCs which run non-vanilla kernels require hacks to steal > > ports from the networking stack for use by proprietary firmware. > > > > I don't see how merging this patch benefits the community. > > This is just a transparent proxy scenario though. > We block the specific ports so that there is no unrelated traffic > belonging to host proxied here incorrectly. It's a form of one, agreed, although let's be honest - someone reading the transparent proxy use case in the commit message will not think of a complex AP scenario, but rather of a locally configured transparent proxy with IPtables or sockets or such.
On Tue, 10 Dec 2019 12:46:29 +0100, Maciej Żenczykowski wrote: > > Okay, that's what I was suspecting. It'd be great if the real > > motivation for a patch was spelled out in the commit message :/ > > It is, but the commit message is already extremely long. Long, yet it doesn't mention the _real_ reason for the patch. > At some point essays and discussions belong in email and not in the > commit message. Ugh just admit you didn't mention the primary use case in the commit log, and we can move on. > Here's another use case: > > A network where firewall policy or network behaviour blocks all > traffic using specific ports. > > I've seen generic firewalls that unconditionally drop all BGP or SMTP > port traffic, or all traffic on ports 5060/5061 (regardless of > direction) or on 25/53/80/123/443/853/3128/8000/8080/8088/8888 > (usually due to some ill guided security policies against sip or open > proxies or xxx). If you happen to use port XXXX as your source port > your connection just hangs (packets are blackholed). > > Sure you can argue the network is broken, but in the real world you > often can't fix it... Go try and convince your ISP that they should > only drop inbound connections to port 8000, but not outgoing > connections from port 8000 - you'll go crazy before you find someone > who even understands what you're talking about - and even if you find > such a person, they'll probably be too busy to change things - and > even though it might be a 1 letter change (port -> dport) - it still > might take months of testing and rollout before it's fully deployed. > > I've seen networks where specific ports are automatically classified > as super high priority (network control) so you don't want anything > using these ports without very good reason (common for BGP for > example, or for encap schemes). > > Or a specific port number being reserved by GUE or other udp encap > schemes and thus unsafe to use for generic traffic (because the > network or even the kernel itself might for example auto decapsulate > it [via tc ebpf for example], or parse the interior of the packet for > flowhashing purposes...). > > [I'll take this opportunity to point out that due to poor flow hashing > behaviour GRE is basically unusable at scale (not to mention poorly > extensible), and thus GUE and other UDP encap schemes are taking over] > > Or you might want to forward udp port 4500 from your external IP to a > dedicated ipsec box or some hardware offload engine... etc. It's networking you can concoct a scenario to justify anything. > > So some SoCs which run non-vanilla kernels require hacks to steal > > ports from the networking stack for use by proprietary firmware. > > I don't see how merging this patch benefits the community. > > I think you're failing to account for the fact that the majority of > Linux users are Android users - there's around 2.5 billion Android > phones in the wild... - but perhaps you don't consider your users (or > Android?) to be part of your community? I don't consider users of non-vanilla kernels to necessarily be a reason to merge patches upstream, no. They carry literally millions of lines of patches out of tree, let them carry this patch, too. If I can't boot a vanilla kernel on those devices, and clearly there is no intent by the device manufacturers for me to ever will, why would I care? Some companies care about upstream, and those should be rewarded by us taking some of the maintenance off their hands. Some don't: https://www.youtube.com/watch?v=_36yNWw_07g (link to Linus+nVidia video) even tho they sell majority of SoCs for 2.5 billion devices. > btw. Chrome OS is also Linux based (and if a quick google search is to > be believed, about 1/7th of the linux desktop/laptop share), but since > it supports running Android apps, it needs to have all Android > specific generic kernel changes... > > The reason Android runs non-vanilla kernels is *because* patches like > this - that make Linux work in the real world - are missing from > vanilla Linux > (I can think of a few other networking patches off the top of my head > where we've been unable to upstream them for no particularly good > reason). The way to get those patches upstream is to have a honest discussion about the use case so people can validate the design. Not by sending a patch with a 5 page commit message which fails to clearly state the motivation for the feature :/
> It's a form of one, agreed, although let's be honest - someone reading > the transparent proxy use case in the commit message will not think of > a complex AP scenario, but rather of a locally configured transparent > proxy with IPtables or sockets or such. Transparent proxy could be implemented using eBPF + XDP and those don't need sockets. However, in that case we do need to block those specific ports to avoid messing with unrelated traffic.
From: Maciej Żenczykowski <zenczykowski@gmail.com> Date: Tue, 10 Dec 2019 12:46:29 +0100 > At some point essays and discussions belong in email and not in the > commit message. Wrong, full details on the context and impetus matter, no matter how voluminous. If you put what you ate for breakfast in the commit log message I wouldn't complain.
On Wed, Dec 11, 2019 at 2:31 AM Jakub Kicinski <jakub.kicinski@netronome.com> wrote: > I don't consider users of non-vanilla kernels to necessarily be a > reason to merge patches upstream, no. They carry literally millions > of lines of patches out of tree, let them carry this patch, too. > If I can't boot a vanilla kernel on those devices, and clearly there is > no intent by the device manufacturers for me to ever will, why would I > care? That's *not* the intent. https://arstechnica.com/gadgets/2019/11/google-outlines-plans-for-mainline-linux-kernel-support-in-android/ > > The reason Android runs non-vanilla kernels is *because* patches like > > this - that make Linux work in the real world - are missing from > > vanilla Linux That's exactly the point here. Saying, "Android will never use mainline, so why should mainline take their patches" is a self-fulfilling prophecy. Obviously, if mainline never takes Android patches, then yes, Android will never be able to use mainline. We do have an Android tree we can take this patch into. But we don't want to take it without at least attempting to get it into mainline first. The use case here is pretty simple. There are many CPUs in a mobile phone. The baseband processor ("modem") implements much of the functionality required by cellular networks, so if you want cellular voice or data, it needs to be able to talk to the network. For many reasons (architectural, power conservation, security), the modem needs to be able to talk directly to the cellular network. This includes, for example, SIP/RTP media streams that go directly to the audio hardware, IKE traffic that is sent directly by the modem because only the modem has the keys, etc. Normally this happens directly on the cellular interface and Linux/Android is unaware of it. But, when using wifi calling (which is an IPsec tunnel over wifi to an endpoint inside the cellular network), the device only has one IPv4 address, and the baseband processor and the application processor (the CPU that runs Linux/Android) have to share it. This means that some ports have to be reserved so that the baseband processor can depend on using them. NAT cannot be used because the 3GPP standards require protocols that are not very NAT-friendly, and because the modem needs to be able to accept unsolicited inbound traffic. Other than "commit message doesn't have a use case", are there technical concerns with this patch?
On Fri, 13 Dec 2019 09:16:03 +0900, Lorenzo Colitti wrote: > On Wed, Dec 11, 2019 at 2:31 AM Jakub Kicinski wrote: > > I don't consider users of non-vanilla kernels to necessarily be a > > reason to merge patches upstream, no. They carry literally millions > > of lines of patches out of tree, let them carry this patch, too. > > If I can't boot a vanilla kernel on those devices, and clearly there is > > no intent by the device manufacturers for me to ever will, why would I > > care? > > That's *not* the intent. > https://arstechnica.com/gadgets/2019/11/google-outlines-plans-for-mainline-linux-kernel-support-in-android/ > > > > The reason Android runs non-vanilla kernels is *because* patches like > > > this - that make Linux work in the real world - are missing from > > > vanilla Linux > > That's exactly the point here. Saying, "Android will never use > mainline, so why should mainline take their patches" is a > self-fulfilling prophecy. Obviously, if mainline never takes Android > patches, then yes, Android will never be able to use mainline. We do > have an Android tree we can take this patch into. But we don't want to > take it without at least attempting to get it into mainline first. > > The use case here is pretty simple. There are many CPUs in a mobile > phone. The baseband processor ("modem") implements much of the > functionality required by cellular networks, so if you want cellular > voice or data, it needs to be able to talk to the network. For many > reasons (architectural, power conservation, security), the modem needs > to be able to talk directly to the cellular network. This includes, > for example, SIP/RTP media streams that go directly to the audio > hardware, IKE traffic that is sent directly by the modem because only > the modem has the keys, etc. Normally this happens directly on the > cellular interface and Linux/Android is unaware of it. But, when using > wifi calling (which is an IPsec tunnel over wifi to an endpoint inside > the cellular network), the device only has one IPv4 address, and the > baseband processor and the application processor (the CPU that runs > Linux/Android) have to share it. This means that some ports have to be > reserved so that the baseband processor can depend on using them. NAT > cannot be used because the 3GPP standards require protocols that are > not very NAT-friendly, and because the modem needs to be able to > accept unsolicited inbound traffic. > > Other than "commit message doesn't have a use case", are there > technical concerns with this patch? Maybe a minor question or two, but the main complaint is the commit message. How are the ports which get reserved communicated between the baseband and the AP? Is this part of the standard? Is the driver that talks to the base band in the user space and it knows which ports to reserve statically? Or does the modem dynamically request ports to reserve/inform the host of ports in use? Should the sysfs interface make sure there are not existing sockets using requested ports which would stop working? If we may need it one day better add it now..
On Fri, Dec 13, 2019 at 9:47 AM Jakub Kicinski <jakub.kicinski@netronome.com> wrote: > How are the ports which get reserved communicated between the baseband > and the AP? Is this part of the standard? Is the driver that talks to > the base band in the user space and it knows which ports to reserve > statically? Or does the modem dynamically request ports to > reserve/inform the host of ports in use? I'm not an expert in that part of the system, but my understanding is that the primary way this is used is to pre-allocate a block of ports to be used by the modem on boot, before other applications can bind to ports. Subash, do you have more details?
On 2019-12-12 17:57, Lorenzo Colitti wrote: > On Fri, Dec 13, 2019 at 9:47 AM Jakub Kicinski > <jakub.kicinski@netronome.com> wrote: >> How are the ports which get reserved communicated between the baseband >> and the AP? Is this part of the standard? Is the driver that talks to >> the base band in the user space and it knows which ports to reserve >> statically? Or does the modem dynamically request ports to >> reserve/inform the host of ports in use? > > I'm not an expert in that part of the system, but my understanding is > that the primary way this is used is to pre-allocate a block of ports > to be used by the modem on boot, before other applications can bind to > ports. Subash, do you have more details? AFAIK these ports are randomly picked and not from a standard. Userspace gets this information through qrtr during boot. Atleast in our case, there cannot be any existing user of these ports since these ports are blocked prior to mobile connection establishment. We could call SOCK_DIAG_DESTROY on these ports from userspace as a precaution as applications would gracefully handle the socket errors.
On Thu, 12 Dec 2019 18:53:19 -0700, subashab@codeaurora.org wrote: > On 2019-12-12 17:57, Lorenzo Colitti wrote: > > On Fri, Dec 13, 2019 at 9:47 AM Jakub Kicinski wrote: > >> How are the ports which get reserved communicated between the baseband > >> and the AP? Is this part of the standard? Is the driver that talks to > >> the base band in the user space and it knows which ports to reserve > >> statically? Or does the modem dynamically request ports to > >> reserve/inform the host of ports in use? > > > > I'm not an expert in that part of the system, but my understanding is > > that the primary way this is used is to pre-allocate a block of ports > > to be used by the modem on boot, before other applications can bind to > > ports. Subash, do you have more details? > > AFAIK these ports are randomly picked and not from a standard. > Userspace gets this information through qrtr during boot. > > Atleast in our case, there cannot be any existing user of these ports > since these ports are blocked prior to mobile connection establishment. Not even a listening socket? > We could call SOCK_DIAG_DESTROY on these ports from userspace as a > precaution as applications would gracefully handle the socket errors. Right, or kernel could walk them, since presumably every application using this functionality should do it, anyway? But no strong feeling on this if nobody else feels this is needed.
diff --git a/Documentation/networking/ip-sysctl.txt b/Documentation/networking/ip-sysctl.txt index fd26788e8c96..7129646a18bd 100644 --- a/Documentation/networking/ip-sysctl.txt +++ b/Documentation/networking/ip-sysctl.txt @@ -940,6 +940,19 @@ ip_local_reserved_ports - list of comma separated ranges Default: Empty +ip_local_unbindable_ports - list of comma separated ranges + Specify the ports which are not directly bind()able. + + Usually you would use this to block the use of ports which + are invalid due to something outside of the control of the + kernel. For example a port stolen by the nic for serial + console, remote power management or debugging. + + There's a relatively high chance you will also want to list + these ports in 'ip_local_reserved_ports' to prevent autobinding. + + Default: Empty + ip_unprivileged_port_start - INTEGER This is a per-namespace sysctl. It defines the first unprivileged port in the network namespace. Privileged ports diff --git a/include/net/ip.h b/include/net/ip.h index 5b317c9f4470..045432e6d18e 100644 --- a/include/net/ip.h +++ b/include/net/ip.h @@ -346,6 +346,13 @@ static inline bool inet_is_local_reserved_port(struct net *net, unsigned short p return test_bit(port, net->ipv4.sysctl_local_reserved_ports); } +static inline bool inet_is_local_unbindable_port(struct net *net, unsigned short port) +{ + if (!net->ipv4.sysctl_local_unbindable_ports) + return false; + return test_bit(port, net->ipv4.sysctl_local_unbindable_ports); +} + static inline bool sysctl_dev_name_is_allowed(const char *name) { return strcmp(name, "default") != 0 && strcmp(name, "all") != 0; @@ -362,6 +369,11 @@ static inline bool inet_is_local_reserved_port(struct net *net, unsigned short p return false; } +static inline bool inet_is_local_unbindable_port(struct net *net, unsigned short port) +{ + return false; +} + static inline bool inet_port_requires_bind_service(struct net *net, unsigned short port) { return port < PROT_SOCK; diff --git a/include/net/netns/ipv4.h b/include/net/netns/ipv4.h index c0c0791b1912..6a235651925d 100644 --- a/include/net/netns/ipv4.h +++ b/include/net/netns/ipv4.h @@ -197,6 +197,7 @@ struct netns_ipv4 { #ifdef CONFIG_SYSCTL unsigned long *sysctl_local_reserved_ports; + unsigned long *sysctl_local_unbindable_ports; int sysctl_ip_prot_sock; #endif diff --git a/net/ipv4/af_inet.c b/net/ipv4/af_inet.c index 2fe295432c24..b26046431612 100644 --- a/net/ipv4/af_inet.c +++ b/net/ipv4/af_inet.c @@ -494,6 +494,10 @@ int __inet_bind(struct sock *sk, struct sockaddr *uaddr, int addr_len, goto out; snum = ntohs(addr->sin_port); + err = -EPERM; + if (snum && inet_is_local_unbindable_port(net, snum)) + goto out; + err = -EACCES; if (snum && inet_port_requires_bind_service(net, snum) && !ns_capable(net->user_ns, CAP_NET_BIND_SERVICE)) diff --git a/net/ipv4/sysctl_net_ipv4.c b/net/ipv4/sysctl_net_ipv4.c index fcb2cd167f64..fd363b57a653 100644 --- a/net/ipv4/sysctl_net_ipv4.c +++ b/net/ipv4/sysctl_net_ipv4.c @@ -745,6 +745,13 @@ static struct ctl_table ipv4_net_table[] = { .mode = 0644, .proc_handler = proc_do_large_bitmap, }, + { + .procname = "ip_local_unbindable_ports", + .data = &init_net.ipv4.sysctl_local_unbindable_ports, + .maxlen = 65536, + .mode = 0644, + .proc_handler = proc_do_large_bitmap, + }, { .procname = "ip_no_pmtu_disc", .data = &init_net.ipv4.sysctl_ip_no_pmtu_disc, @@ -1353,11 +1360,17 @@ static __net_init int ipv4_sysctl_init_net(struct net *net) net->ipv4.sysctl_local_reserved_ports = kzalloc(65536 / 8, GFP_KERNEL); if (!net->ipv4.sysctl_local_reserved_ports) - goto err_ports; + goto err_reserved_ports; + + net->ipv4.sysctl_local_unbindable_ports = kzalloc(65536 / 8, GFP_KERNEL); + if (!net->ipv4.sysctl_local_unbindable_ports) + goto err_unbindable_ports; return 0; -err_ports: +err_unbindable_ports: + kfree(net->ipv4.sysctl_local_reserved_ports); +err_reserved_ports: unregister_net_sysctl_table(net->ipv4.ipv4_hdr); err_reg: if (!net_eq(net, &init_net)) @@ -1370,6 +1383,7 @@ static __net_exit void ipv4_sysctl_exit_net(struct net *net) { struct ctl_table *table; + kfree(net->ipv4.sysctl_local_unbindable_ports); kfree(net->ipv4.sysctl_local_reserved_ports); table = net->ipv4.ipv4_hdr->ctl_table_arg; unregister_net_sysctl_table(net->ipv4.ipv4_hdr); diff --git a/net/ipv6/af_inet6.c b/net/ipv6/af_inet6.c index d727c3b41495..41f453906f2f 100644 --- a/net/ipv6/af_inet6.c +++ b/net/ipv6/af_inet6.c @@ -292,6 +292,8 @@ static int __inet6_bind(struct sock *sk, struct sockaddr *uaddr, int addr_len, return -EINVAL; snum = ntohs(addr->sin6_port); + if (snum && inet_is_local_unbindable_port(net, snum)) + return -EPERM; if (snum && inet_port_requires_bind_service(net, snum) && !ns_capable(net->user_ns, CAP_NET_BIND_SERVICE)) return -EACCES; diff --git a/net/sctp/socket.c b/net/sctp/socket.c index 0b485952a71c..d1c93542419d 100644 --- a/net/sctp/socket.c +++ b/net/sctp/socket.c @@ -384,6 +384,9 @@ static int sctp_do_bind(struct sock *sk, union sctp_addr *addr, int len) } } + if (snum && inet_is_local_unbindable_port(net, snum)) + return -EPERM; + if (snum && inet_port_requires_bind_service(net, snum) && !ns_capable(net->user_ns, CAP_NET_BIND_SERVICE)) return -EACCES; @@ -1061,6 +1064,8 @@ static int sctp_connect_new_asoc(struct sctp_endpoint *ep, if (sctp_autobind(sk)) return -EAGAIN; } else { + if (inet_is_local_unbindable_port(net, ep->base.bind_addr.port)) + return -EPERM; if (inet_port_requires_bind_service(net, ep->base.bind_addr.port) && !ns_capable(net->user_ns, CAP_NET_BIND_SERVICE)) return -EACCES;