Features

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Table of security features in Ubuntu: <<TableOfContents>>
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== Feature Matrix ==
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|| Configurable Firewall ||<#98fd98> iptables ||<#00dd00> ufw ||<#00dd00> ufw ||<#00dd00> ufw (installer integration) ||<#00dd00> ufw || || Configurable Firewall ||<#98fd98> iptables ||<#00dd00> ufw ||<#00dd00> ufw ||<#00dd00> ufw                        ||<#00dd00> ufw ||
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== No Open Ports ==
By policy, default installations of Ubuntu must have no listening network services after initial install. Exceptions to this rule include network infrastructure services such as DHCP and Avahi. When installing Ubuntu Server, the administrator can, of course, select specific services to install beyond the defaults (e.g. Apache).

== Password hashing ==
The system password used for logging into Ubuntu is stored in /etc/shadow. Very old style password hashes were 3DES and visible in /etc/passwd. Modern Linux has long since moved to /etc/shadow, and for some time now has used salted MD5 hashes for password verification. Since MD5 is considered "broken", Ubuntu has moved to using salted SHA512 password hashes, which are several orders of magnitude more difficult to brute-force or generate rainbow tables.

== Mandatory Access Control (MAC) ==
Mandatory Access Controls are handled via the kernel LSM hooks.

=== AppArmor ===
[[https://help.ubuntu.com/community/AppArmor|AppArmor]] is a path-based MAC. Examples profiles are found in the apparmor-profiles package from universe, and by-default shipped [[SecurityTeam/KnowledgeBase/AppArmorProfiles|enforcing profiles]] are being built up:

<<Include(SecurityTeam/KnowledgeBase/AppArmorProfiles, , from="=== Enforcing Profiles in Main ===", to="===")>>

=== SELinux ===
[[SELinux]] is an inode-based MAC. Targetted policies are available for Ubuntu in universe. Installing the "selinux" package will make the boot-time adjustments that are needed.

== FS Capabilities ==
The need for setuid applications can be reduced via the application of [[http://www.olafdietsche.de/linux/capability/|filesystem capabilities]] using the xattrs available to most modern filesystems. This reduces the possible misuse of vulnerable setuid applications. The kernel provides the support, and the user-space tools are in main ("libcap2-bin").

== Configurable Firewall ==
[[UbuntuFirewall|ufw]] is a frontend for iptables, and is installed by default in Ubuntu (users must explicitly enable it). Particularly well-suited for host-based firewalls, ufw provides a framework for managing a netfilter firewall, as well as a command-line interface for manipulating the firewall. ufw aims to provide an easy to use interface for people unfamiliar with firewall concepts, while at the same time simplifies complicated iptables commands to help an adminstrator who knows what he or she is doing. ufw is an upstream for other distributions and graphical frontends.

== Filesystem encryption ==
=== Encrypted LVM ===
Users of the alternate installer can choose to install Ubuntu onto an encrypted LVM, which allows all partitions in the logical volume, including swap, to be encrypted.

=== eCryptfs ===
Encrypted Private Directories were implemented in Ubuntu 8.10 as a secure location for users to store sensitive information. The server and alternate installers had the option to setup an encrypted private directory for the first user. As of Ubuntu 9.04, support for encrypted home was added, allowing users to encrypt all files in their home directory. Encrypted Home is supported in the Alternate Installer, and available in the Desktop Installer via the preseed option '''user-setup/encrypt-home=true'''. Also, the Ubuntu 9.04 kernel carries a patchset for eCryptfs to support encrypted filenames.

== Hardening ==
Many compile-time features are available through the default [[CompilerFlags|compiler flags]] in Ubuntu.

=== Stack Protector ===
gcc's -fstack-protector provides a randomized stack canary that protects against stack overflows, and reduces the chances of arbitrary code execution via controlling return address destinations. Enabled at compile-time. (A small number of applications do not play well with it, and have it disabled.) The routines used for stack checking are actually part of glibc, but gcc is patched to enable linking against those routines by default.

=== Heap Protector ===
The [[http://www.cs.ucsb.edu/~wkr/projects/heap_protection/|heap protector]] provides double-free/overflow protections to the glibc heap memory manager (first introduced in glibc 2.3.4). This stops the ability to perform arbitrary code execution via heap memory overflows that try to impact the malloc linked lists.

=== libc pointer encryption ===
Some [[http://udrepper.livejournal.com/13393.html|pointers stored in glibc are obfuscated]] via PTR_MANGLE/PTR_UNMANGLE macros internally in glibc, preventing libc function pointers from being overwritten during runtime.

=== stack ASLR ===
Each execution of a program results in a different stack memory space layout. This makes it harder to locate in memory where to attack or deliver an executable attack payload. This was available in the mainline kernel since 2.6.15 (Ubuntu 6.06).

=== mmap ASLR ===
Each execution of a program results in a different mmap memory space layout (which causes the dynamically loaded libraries to get loaded into different locations each time). This makes it harder to locate in memory where to jump to for "return to libc" to similar attacks. This was available in the mainline kernel since 2.6.15 (Ubuntu 6.06).

=== exec ASLR ===
Each execution of a program that has been built with "-fPIE -pie" will get loaded into a different memory location. This makes it harder to locate in memory where to attack or jump to when performing memory-corruption-based attacks. This was available in the mainline kernel since 2.6.25 (and was backported to Ubuntu 8.04).

=== brk ASLR ===
Similar to exec ASLR, brk ASLR adjusts the memory locations relative between the exec memory area and the brk memory area (for small mallocs). The randomization of brk offset from exec memory was added in 2.6.26, though some of the effects of brk ASLR can be seen in Ubuntu 8.04 since exec was ASLR, and brk is allocated immediately after the exec region (so it was technically randomized, but not randomized with respect to the text region until 8.10).

=== vdso ASLR ===
Each execution of a program results in a random vdso location. While this has existed in the mainline kernel since 2.6.18 (x86, PPC) and 2.6.22 (x86_64), it hadn't been enabled in Ubuntu 6.06 due to COMPAT_VDSO being enable, which was disabled in Ubuntu 8.04. This protects against jump-into-syscall attacks. Only x86 (maybe ppc?) is supported by glibc 2.6. glibc 2.7 (Ubuntu 8.04) supports x86_64 ASLR vdso. People needing ancient pre-libc6 static high vdso mappings can use "vdso=2" on the kernel boot command line to gain COMPAT_VDSO again.

 * http://lwn.net/Articles/184734/
 * http://manugarg.googlepages.com/systemcallinlinux2_6.html

=== PIE ===
All programs built with "-fPIE -pie" can take advantage of the exec ASLR. This protects against "return-to-text" and generally frustrates memory corruption attacks. This requires centralized changes to the compiler options when building the entire archive. PIE has a large (5-10%) performance penalty on architectures with small numbers of general registers (e.g. x86), so it should only be used for a [[SecurityTeam/KnowledgeBase/BuiltPIE|select number of security-critical packages]] (some upstreams natively support building with PIE, other require the use of "hardening-wrapper" to force on the correct compiler and linker flags). PIE on x86_64 does not have the same penalties, and will eventually be made the default, but more testing is required.

<<Include(SecurityTeam/KnowledgeBase/BuiltPIE, , from="== Built as Position Independent Executables ==", to="---")>>

=== Fortify Source ===
Programs built with "-D_FORTIFY_SOURCE=2" (and -O2 or higher), enable several compile-time and run-time protections in glibc:
 * expand unbounded calls to "sprintf", "strcpy" into their "n" length-limited cousins when the size of a destination buffer is known (protects against memory overflows)
 * stop format string "%n" attacks when the format string is in a writeable memory segment
 * require checking various important function return codes and arguments (e.g. system, write, open).
 * require explicit file mask when creating new files.

=== relro ===
Hardens ELF programs against loader memory area overwrites. This reduces the area of possible GOT-overwrite-style memory corruption attacks.

=== BIND_NOW ===
Marks ELF programs to resolve all dynamic symbols at start-up (instead of on-demand) so that the GOT can be made entirely read-only (when combined with relro above).

=== Non-Exec Memory ===
Most modern CPUs protect against executing non-executable memory regions (heap, stack, etc), but requires that the kernel use "PAE" addressing. This is the default for 64bit and on the ia32 -server kernels. This protection reduces the areas an attacker can use to perform arbitrary code execution. The protection is partially emulated on ia32 without PAE starting in Ubuntu 9.10.

=== /proc/$pid/maps protection ===
With ASLR, a process's memory space layout suddenly becomes valuable to attackers. The "maps" file is [[http://lkml.org/lkml/2007/3/10/250|made read-only]] except to the process itself or the owner of the process. Went into mainline kernel with sysctl toggle in 2.6.22. The toggle was made non-optional in 2.6.27, forcing the privacy to be enabled regardless of sysctl settings (this is a good thing).

=== 0-address protection ===
Since the kernel and userspace share virtual memory addresses, the "NULL" memory space needs to be protected so that userspace mmap'd memory cannot start at address 0, stopping "NULL dereference" kernel attacks. This is possible with 2.6.22 kernels, and was implemented with the "mmap_min_addr" sysctl setting. Since Ubuntu 9.04, the mmap_min_addr setting is built into the kernel. (64k for x86, 32k for ARM.)

=== /dev/mem protection ===
Some applications (Xorg) need direct access to the physical memory from user-space. The special file /dev/mem exists to provide this access. In the past, it was possible to view and change kernel memory from this file if an attacker had root access. The [[http://lwn.net/Articles/267427/|CONFIG_STRICT_DEVMEM kernel option]] was introduced to block non-device memory access (originally named CONFIG_NONPROMISC_DEVMEM).

=== /dev/kmem disabled ===
There is no modern user of /dev/kmem any more beyond attackers using it to load kernel rootkits. [[http://lkml.org/lkml/2008/2/10/328|CONFIG_DEVKMEM]] is set to "n".

=== CONFIG_DEBUG_RODATA ===
This kernel setting makes sure that certain kernel data sections are not marked to allow modification. This helps protect against some classes of kernel rootkits.

=== CONFIG_CC_STACKPROTECTOR ===
Similar to the stack protector used for ELF programs in userspace, the kernel can protect its internal stacks as well.

== SYN cookies ==
When a system is overwhelmed by new network connections, SYN cookie use is activated, which helps mitigate a SYN-flood attack.

== PR_SET_SECCOMP ==
Setting [[http://lwn.net/Articles/332974/|SECCOMP]] for a process is meant to confine it to a small subsystem of system calls, used for specialized processing-only programs.

== Additional Documentation ==
 * Coordination with Debian: http://wiki.debian.org/Hardening
 * Gentoo's Hardening project: http://www.gentoo.org/proj/en/hardened/hardened-toolchain.xml

Feature Matrix

By Default

Available

Unimplemented

feature

6.06 LTS

8.04 LTS

8.10

9.04

9.10

No Open Ports

policy

policy

policy

policy

policy

Password hashing

md5

md5

sha512

sha512

sha512

AppArmor

--

2.1+svn1075

2.3

2.3

2.3.1

SELinux

--

2.0.55 (universe)

universe

universe

universe

SMACK

--

--

kernel

kernel

kernel

FS capabilities

--

--

kernel

kernel

kernel

Configurable Firewall

iptables

ufw

ufw

ufw

ufw

Encrypted LVM

alt installer

alt installer

alt installer

alt installer

installer

eCryptfs

--

--

~/Private

~/Private or ~, filenames

~/Private or ~, filenames

Stack Protector

--

gcc patch

gcc patch

gcc patch

gcc patch

Heap Protector

glibc

glibc

glibc

glibc

glibc

libc pointer obfuscation

--

glibc

glibc

glibc

glibc

stack ASLR

kernel

kernel

kernel

kernel

kernel

mmap/libs ASLR

kernel (i386 only)

kernel

kernel

kernel

kernel

exec ASLR

--

kernel (-mm patch)

kernel

kernel

kernel

brk ASLR

--

kernel (exec ASLR)

kernel

kernel

kernel

vdso ASLR

--

kernel

kernel

kernel

kernel

Built as PIE

--

--

package list

package list

package list

Built w/ Fortify Source

--

--

gcc patch

gcc patch

gcc patch

Built w/ relro

--

--

gcc patch

gcc patch

gcc patch

Built w/ BIND_NOW

--

--

--

--

package list

Non-Exec Memory

PAE only

PAE only

PAE only

PAE only

PAE, ia32 partial-NX-emulation

/proc/$pid/maps protection

--

kernel & sysctl

kernel

kernel

kernel

0-address protection

--

kernel & sysctl

kernel & sysctl

kernel

kernel

/dev/mem protection

kernel

kernel (-mm patch)

kernel

kernel

kernel

/dev/kmem disabled

--

kernel (-mm patch)

kernel

kernel

kernel

PR_SET_SECCOMP

--

kernel

kernel

kernel

kernel

SYN cookies

kernel

kernel

kernel

kernel & sysctl

kernel & sysctl

CONFIG_DEBUG_RODATA

--

kernel

kernel

kernel

kernel

CONFIG_CC_STACKPROTECTOR

--

--

--

--

kernel

No Open Ports

By policy, default installations of Ubuntu must have no listening network services after initial install. Exceptions to this rule include network infrastructure services such as DHCP and Avahi. When installing Ubuntu Server, the administrator can, of course, select specific services to install beyond the defaults (e.g. Apache).

Password hashing

The system password used for logging into Ubuntu is stored in /etc/shadow. Very old style password hashes were 3DES and visible in /etc/passwd. Modern Linux has long since moved to /etc/shadow, and for some time now has used salted MD5 hashes for password verification. Since MD5 is considered "broken", Ubuntu has moved to using salted SHA512 password hashes, which are several orders of magnitude more difficult to brute-force or generate rainbow tables.

Mandatory Access Control (MAC)

Mandatory Access Controls are handled via the kernel LSM hooks.

AppArmor

AppArmor is a path-based MAC. Examples profiles are found in the apparmor-profiles package from universe, and by-default shipped enforcing profiles are being built up:

Include: Nothing found for "=== Enforcing Profiles in Main ==="!

AppArmor Profiles

AppArmor is installed and loaded by default starting with Ubuntu 7.10 (Gutsy). Some packages will install their own profiles (usually in enforcing mode), while additional profiles can be found in the apparmor-profiles and apparmor-profiles-extra packages from the Universe repository.

SELinux

SELinux is an inode-based MAC. Targetted policies are available for Ubuntu in universe. Installing the "selinux" package will make the boot-time adjustments that are needed.

FS Capabilities

The need for setuid applications can be reduced via the application of filesystem capabilities using the xattrs available to most modern filesystems. This reduces the possible misuse of vulnerable setuid applications. The kernel provides the support, and the user-space tools are in main ("libcap2-bin").

Configurable Firewall

ufw is a frontend for iptables, and is installed by default in Ubuntu (users must explicitly enable it). Particularly well-suited for host-based firewalls, ufw provides a framework for managing a netfilter firewall, as well as a command-line interface for manipulating the firewall. ufw aims to provide an easy to use interface for people unfamiliar with firewall concepts, while at the same time simplifies complicated iptables commands to help an adminstrator who knows what he or she is doing. ufw is an upstream for other distributions and graphical frontends.

Filesystem encryption

Encrypted LVM

Users of the alternate installer can choose to install Ubuntu onto an encrypted LVM, which allows all partitions in the logical volume, including swap, to be encrypted.

eCryptfs

Encrypted Private Directories were implemented in Ubuntu 8.10 as a secure location for users to store sensitive information. The server and alternate installers had the option to setup an encrypted private directory for the first user. As of Ubuntu 9.04, support for encrypted home was added, allowing users to encrypt all files in their home directory. Encrypted Home is supported in the Alternate Installer, and available in the Desktop Installer via the preseed option user-setup/encrypt-home=true. Also, the Ubuntu 9.04 kernel carries a patchset for eCryptfs to support encrypted filenames.

Hardening

Many compile-time features are available through the default compiler flags in Ubuntu.

Stack Protector

gcc's -fstack-protector provides a randomized stack canary that protects against stack overflows, and reduces the chances of arbitrary code execution via controlling return address destinations. Enabled at compile-time. (A small number of applications do not play well with it, and have it disabled.) The routines used for stack checking are actually part of glibc, but gcc is patched to enable linking against those routines by default.

Heap Protector

The heap protector provides double-free/overflow protections to the glibc heap memory manager (first introduced in glibc 2.3.4). This stops the ability to perform arbitrary code execution via heap memory overflows that try to impact the malloc linked lists.

libc pointer encryption

Some pointers stored in glibc are obfuscated via PTR_MANGLE/PTR_UNMANGLE macros internally in glibc, preventing libc function pointers from being overwritten during runtime.

stack ASLR

Each execution of a program results in a different stack memory space layout. This makes it harder to locate in memory where to attack or deliver an executable attack payload. This was available in the mainline kernel since 2.6.15 (Ubuntu 6.06).

mmap ASLR

Each execution of a program results in a different mmap memory space layout (which causes the dynamically loaded libraries to get loaded into different locations each time). This makes it harder to locate in memory where to jump to for "return to libc" to similar attacks. This was available in the mainline kernel since 2.6.15 (Ubuntu 6.06).

exec ASLR

Each execution of a program that has been built with "-fPIE -pie" will get loaded into a different memory location. This makes it harder to locate in memory where to attack or jump to when performing memory-corruption-based attacks. This was available in the mainline kernel since 2.6.25 (and was backported to Ubuntu 8.04).

brk ASLR

Similar to exec ASLR, brk ASLR adjusts the memory locations relative between the exec memory area and the brk memory area (for small mallocs). The randomization of brk offset from exec memory was added in 2.6.26, though some of the effects of brk ASLR can be seen in Ubuntu 8.04 since exec was ASLR, and brk is allocated immediately after the exec region (so it was technically randomized, but not randomized with respect to the text region until 8.10).

vdso ASLR

Each execution of a program results in a random vdso location. While this has existed in the mainline kernel since 2.6.18 (x86, PPC) and 2.6.22 (x86_64), it hadn't been enabled in Ubuntu 6.06 due to COMPAT_VDSO being enable, which was disabled in Ubuntu 8.04. This protects against jump-into-syscall attacks. Only x86 (maybe ppc?) is supported by glibc 2.6. glibc 2.7 (Ubuntu 8.04) supports x86_64 ASLR vdso. People needing ancient pre-libc6 static high vdso mappings can use "vdso=2" on the kernel boot command line to gain COMPAT_VDSO again.

PIE

All programs built with "-fPIE -pie" can take advantage of the exec ASLR. This protects against "return-to-text" and generally frustrates memory corruption attacks. This requires centralized changes to the compiler options when building the entire archive. PIE has a large (5-10%) performance penalty on architectures with small numbers of general registers (e.g. x86), so it should only be used for a select number of security-critical packages (some upstreams natively support building with PIE, other require the use of "hardening-wrapper" to force on the correct compiler and linker flags). PIE on x86_64 does not have the same penalties, and will eventually be made the default, but more testing is required.

Include: Nothing found for "== Built as Position Independent Executables =="!

Historical

This page is for historical purposes only. As of 16.10, PIE is enabled by default for amd64, ppc64el and s390x. As of 17.10, PIE is enabled by default for all architectures in the Ubuntu archive.

These packages are built with "hardening-wrapper", or similar native build options. The primary purpose is to gain PIE (and as of Ubuntu 9.10, -Wl,-z,now).

Supported Position Independent Executables in main

Source package

8.04 LTS

9.04

9.10

10.04 LTS

10.10

11.04

11.10

openssh (native)

yes

yes

yes

yes

yes

yes

yes

apache2

--

yes

yes

yes

yes

yes

yes

bind9

--

yes

yes

yes

yes

yes

yes

openldap

--

yes

yes

yes

yes

yes

yes

postfix

--

yes

yes

yes

yes

yes

yes

cups

--

yes

yes

yes

yes

yes

yes

postgresql-8.3

--

yes

yes

yes

yes

yes

yes

samba (native)

--

yes

yes

yes

yes

yes

yes

dovecot

--

yes

yes

yes

yes

yes

yes

dhcp3

--

yes

yes

yes

yes

yes

yes

ntp

--

--

yes

yes

yes

yes

yes

amavisd-new

--

--

yes

yes

yes

yes

yes

squid

--

--

yes

yes

yes

yes

yes

cyrus-sasl2

--

--

yes

yes

yes

yes

yes

exim4

--

--

yes

yes

yes

yes

yes

nagios3

--

--

yes

yes

yes

yes

yes

nagios-plugins

--

--

yes

yes

yes

yes

yes

xinetd

--

--

yes

yes

yes

yes

yes

ipsec-tools

--

--

yes

yes

yes

yes

yes

mysql-dfsg-5.1

--

--

yes

yes

yes

yes

yes

evince

--

--

--

yes

yes

yes

yes

firefox

--

--

--

yes

yes

yes

yes

gnome-control-center

--

--

--

--

--

yes

yes

tiff

--

--

--

--

--

yes

yes

totem

--

--

--

--

--

yes

yes

qemu-kvm

--

--

--

--

--

--

yes

pidgin

--

--

--

--

--

--

yes

Community supported Position Independent Executables

Source package

8.04 LTS

9.04

9.10

10.04 LTS

10.10

11.04

11.10

asterisk

--

--

yes

yes

yes

yes

yes

sendmail

--

--

yes

yes

yes

yes

yes

openbsd-inetd

--

--

yes

yes

yes

yes

yes

wireshark

--

--

yes

yes

yes

yes

yes

chromium-browser

--

--

--

yes

yes

yes

yes

Fortify Source

Programs built with "-D_FORTIFY_SOURCE=2" (and -O2 or higher), enable several compile-time and run-time protections in glibc:

  • expand unbounded calls to "sprintf", "strcpy" into their "n" length-limited cousins when the size of a destination buffer is known (protects against memory overflows)
  • stop format string "%n" attacks when the format string is in a writeable memory segment
  • require checking various important function return codes and arguments (e.g. system, write, open).
  • require explicit file mask when creating new files.

relro

Hardens ELF programs against loader memory area overwrites. This reduces the area of possible GOT-overwrite-style memory corruption attacks.

BIND_NOW

Marks ELF programs to resolve all dynamic symbols at start-up (instead of on-demand) so that the GOT can be made entirely read-only (when combined with relro above).

Non-Exec Memory

Most modern CPUs protect against executing non-executable memory regions (heap, stack, etc), but requires that the kernel use "PAE" addressing. This is the default for 64bit and on the ia32 -server kernels. This protection reduces the areas an attacker can use to perform arbitrary code execution. The protection is partially emulated on ia32 without PAE starting in Ubuntu 9.10.

/proc/$pid/maps protection

With ASLR, a process's memory space layout suddenly becomes valuable to attackers. The "maps" file is made read-only except to the process itself or the owner of the process. Went into mainline kernel with sysctl toggle in 2.6.22. The toggle was made non-optional in 2.6.27, forcing the privacy to be enabled regardless of sysctl settings (this is a good thing).

0-address protection

Since the kernel and userspace share virtual memory addresses, the "NULL" memory space needs to be protected so that userspace mmap'd memory cannot start at address 0, stopping "NULL dereference" kernel attacks. This is possible with 2.6.22 kernels, and was implemented with the "mmap_min_addr" sysctl setting. Since Ubuntu 9.04, the mmap_min_addr setting is built into the kernel. (64k for x86, 32k for ARM.)

/dev/mem protection

Some applications (Xorg) need direct access to the physical memory from user-space. The special file /dev/mem exists to provide this access. In the past, it was possible to view and change kernel memory from this file if an attacker had root access. The CONFIG_STRICT_DEVMEM kernel option was introduced to block non-device memory access (originally named CONFIG_NONPROMISC_DEVMEM).

/dev/kmem disabled

There is no modern user of /dev/kmem any more beyond attackers using it to load kernel rootkits. CONFIG_DEVKMEM is set to "n".

CONFIG_DEBUG_RODATA

This kernel setting makes sure that certain kernel data sections are not marked to allow modification. This helps protect against some classes of kernel rootkits.

CONFIG_CC_STACKPROTECTOR

Similar to the stack protector used for ELF programs in userspace, the kernel can protect its internal stacks as well.

SYN cookies

When a system is overwhelmed by new network connections, SYN cookie use is activated, which helps mitigate a SYN-flood attack.

PR_SET_SECCOMP

Setting SECCOMP for a process is meant to confine it to a small subsystem of system calls, used for specialized processing-only programs.

Additional Documentation

Security/Features (last edited 2024-10-22 08:49:04 by jjohansen)