haproxy/INSTALL

664 lines
32 KiB
Plaintext
Raw Normal View History

Installation instructions for HAProxy
=====================================
This is a development version, so it is expected to break from time to time,
to add and remove features without prior notification and it should not be used
in production. If you are not used to build from sources or if you are not used
to follow updates then it is recommended that instead you use the packages
provided by your software vendor or Linux distribution. Most of them are taking
this task seriously and are doing a good job at backporting important fixes. If
for any reason you'd prefer to use a different version than the one packaged
for your system, you want to be certain to have all the fixes or to get some
commercial support, other choices are available at http://www.haproxy.com/.
Areas covered in this document
==============================
1) Quick build & install
2) Basic principles
3) Build environment
4) Dependencies
5) Advanced build options
6) How to install HAProxy
1) Quick build & install
========================
If you've already built HAProxy and are just looking for a quick reminder, here
are a few build examples :
- recent Linux system with all options, make and install :
$ make clean
$ make -j $(nproc) TARGET=linux-glibc \
USE_OPENSSL=1 USE_LUA=1 USE_PCRE=1 USE_SYSTEMD=1
$ sudo make install
- FreeBSD and OpenBSD, build with all options :
$ gmake -j 4 TARGET=freebsd USE_OPENSSL=1 USE_LUA=1 USE_PCRE=1
- embedded Linux, build using a cross-compiler :
$ make -j $(nproc) TARGET=linux-glibc USE_OPENSSL=1 USE_PCRE=1 \
CC=/opt/cross/gcc730-arm/bin/gcc ADDLIB=-latomic
- Build with static PCRE on Solaris / UltraSPARC :
$ make TARGET=solaris CPU=ultrasparc USE_STATIC_PCRE=1
For more advanced build options or if a command above reports an error, please
read the following sections.
2) Basic principles
===================
HAProxy uses a single GNU Makefile which supports options on the command line,
so that there is no need to hack a "configure" file to work on your system. The
makefile totally supports parallel build using "make -j <jobs>" where <jobs>
matches the number of usable processors, which on some platforms is returned by
the "nproc" utility. The explanations below may occasionally refer to some
options, usually in the form "name=value", which have to be passed to the
command line. This means that the option has to be passed after the "make"
command. For example :
$ make -j $(nproc) TARGET=generic USE_GZIP=1
One required option is TARGET, it must be set to a target platform name, which
provides a number of presets. The list of known platforms is displayed when no
target is specified. It is not strictly required to use the exact target, you
can use a relatively similar one and adjust specific variables by hand.
Most configuration variables are in fact booleans. Some options are detected and
enabled by default if available on the target platform. This is the case for all
those named "USE_<feature>". These booleans are enabled by "USE_<feature>=1"
and are disabled by "USE_<feature>=" (with no value). An exhaustive list of the
supported USE_* features is located at the top of the main Makefile. The last
occurrence of such an option on the command line overrides any previous one.
Example :
$ make TARGET=generic USE_THREAD=
In case of error or missing TARGET, a help screen is displayed. It is also
possible to display a list of all known options using "make help".
Some optional components which may depend on third-party libraries, are used
with popular tools which are not necessarily standard implementations, or are
maintained at slower pace than the core of the project, are located in the
"addons/" directory. These ones may disappear in a future version if the
product they depend on disappears or if their maintainers do not assign enough
resources to maintain them any more. For this reason they are not built by
default, but some USE_* options are usually provided for them, and their build
is routinely tested anyway.
3) Build environment
====================
HAProxy requires a working GCC or Clang toolchain and GNU make :
- GNU make >= 3.80. Note that neither Solaris nor OpenBSD's make work with
the GNU Makefile. If you get many syntax errors when running "make", you
may want to retry with "gmake" which is the name commonly used for GNU make
on BSD systems.
- GCC >= 4.2 (up to 12 tested). Older versions can be made to work with a
few minor adaptations if really needed. Newer versions may sometimes break
due to compiler regressions or behaviour changes. The version shipped with
your operating system is very likely to work with no trouble. Clang >= 3.0
is also known to work as an alternative solution. Recent versions may emit
a bit more warnings that are worth reporting as they may reveal real bugs.
TCC (https://repo.or.cz/tinycc.git) is also usable for developers but will
not support threading and was found at least once to produce bad code in
some rare corner cases (since fixed). But it builds extremely quickly
(typically half a second for the whole project) and is very convenient to
run quick tests during API changes or code refactoring.
- GNU ld (binutils package), with no particular version. Other linkers might
work but were not tested.
On debian or Ubuntu systems and their derivatives, you may get all these tools
at once by issuing the two following commands :
$ sudo apt-get update
$ sudo apt-get install build-essential
On Fedora, CentOS, RHEL and derivatives, you may get the equivalent packages
with the following command :
$ sudo yum groupinstall "Development Tools"
Please refer to your operating system's documentation for other systems.
It is also possible to build HAProxy for another system or platform using a
cross-compiler but in this case you probably already have installed these
tools.
Building HAProxy may require between 60 and 80 MB of free space in the
directory where the sources have been extracted, depending on the debugging
options involved.
4) Dependencies
===============
HAProxy in its basic form does not depend on anything beyond a working libc.
However a number of options are enabled by default, or are highly recommended,
and these options will typically involve some external components or libraries,
depending on the targeted platform.
Optional dependencies may be split into several categories :
- memory allocation
- regular expressions
- multi-threading
- password encryption
- cryptography
- compression
- lua
- device detection
- miscellaneous
4.1) Memory allocation
----------------------
By default, HAProxy uses the standard malloc() call provided by the libc. It
may also be built to use jemalloc, which is fast and thread-safe. In order to
use it, please add "-ljemalloc" to the ADDLIB variable. You may possibly also
need to append "-lpthread" and/or "-ldl" depending on the operating system.
4.2) Regular expressions
------------------------
HAProxy may make use regular expressions (regex) to match certain patterns. The
regex engine is provided by default in the libc. On some operating systems, it
might happen that the original regex library provided by the libc is too slow,
too limited or even bogus. For example, on older Solaris versions up to 8, the
default regex used not to properly extract group references, without reporting
compilation errors. Also, some early versions of the GNU libc used to include a
regex engine which could be slow or even crash on certain patterns.
If you plan on importing a particularly heavy configuration involving a lot of
regex, you may benefit from using some alternative regex implementations such as
PCRE. HAProxy natively supports PCRE and PCRE2, both in standard and JIT
flavors (Just In Time). The following options are available depending on the
library version provided on your system :
- "USE_PCRE=1" : enable PCRE version 1, dynamic linking
- "USE_STATIC_PCRE=1" : enable PCRE version 1, static linking
- "USE_PCRE_JIT=1" : enable PCRE version 1 in JIT mode
- "USE_PCRE2=1" : enable PCRE version 2, dynamic linking
- "USE_STATIC_PCRE2=1" : enable PCRE version 2, static linking
- "USE_PCRE2_JIT=1" : enable PCRE version 2 in JIT mode
Both of these libraries may be downloaded from https://www.pcre.org/.
By default, the include and library paths are figured from the "pcre-config"
and "pcre2-config" utilities. If these ones are not installed or inaccurate
(for example when cross-compiling), it is possible to force the path to include
files using "PCRE_INC" and "PCRE2_INC" respectively, and the path to library
files using "PCRE_LIB" and "PCRE2_LIB" respectively. For example :
$ make TARGET=generic \
USE_PCRE2_JIT=1 PCRE2_INC=/opt/cross/include PCRE2_LIB=/opt/cross/lib
4.3) Multi-threading
--------------------
On some systems for which positive feedback was reported, multi-threading will
be enabled by default. When multi-threading is used, the libpthread library
(POSIX threading) will be used. If the target system doesn't contain such a
library, it is possible to forcefully disable multi-threading by adding
"USE_THREAD=" on the command line.
4.4) Password encryption
------------------------
Many systems provide password encryption functions used for authentication. On
some systems these functions are part of the libc. On others, they're part of a
separate library called "libcrypt". The default targets are pre-configured
based on which system needs the library. It is possible to forcefully disable
the linkage against libcrypt by adding "USE_LIBCRYPT=" on the command line, or
to forcefully enable it using "USE_LIBCRYPT=1".
4.5) Cryptography
-----------------
For SSL/TLS, it is necessary to use a cryptography library. HAProxy currently
supports the OpenSSL library, and is known to build and work with branches
0.9.8, 1.0.0, 1.0.1, 1.0.2, 1.1.0 and 1.1.1. OpenSSL follows a long-term
support cycle similar to HAProxy's, and each of the branches above receives its
own fixes, without forcing you to upgrade to another branch. There is no excuse
for staying vulnerable by not applying a fix available for your version. There
is always a small risk of regression when jumping from one branch to another
one, especially when it's very new, so it's preferable to observe for a while
if you use a different version than your system's defaults.
Three OpenSSL derivatives called LibreSSL, BoringSSL and QUICTLS are reported
to work as well. While there are some efforts from the community to ensure they
work well, OpenSSL remains the primary target and this means that in case of
conflicting choices, OpenSSL support will be favored over other options. Note
that OpenSSL is not compatible when building haproxy with QUIC support. In this
case, QUICTLS is the preferred alternative. See the section about QUIC in this
document.
In order to enable SSL/TLS support, simply pass "USE_OPENSSL=1" on the command
line and the default library present on your system will be used :
$ make TARGET=generic USE_OPENSSL=1
If you want to use a different version from the one provided by your system
(which is not recommended due to the risk of missing security fixes), it is
possible to indicate the path to the SSL include files using SSL_INC, and the
SSL library files using SSL_LIB. Example :
$ make TARGET=generic \
USE_OPENSSL=1 SSL_INC=/opt/ssl-1.1.1/include SSL_LIB=/opt/ssl-1.1.1/lib
In order to link OpenSSL statically against HAProxy, first download OpenSSL
from https://www.openssl.org/ then build it with the "no-shared" keyword and
install it to a local directory, so your system is not affected :
$ export STATICLIBSSL=/tmp/staticlibssl
$ ./config --prefix=$STATICLIBSSL no-shared
$ make && make install_sw
Then when building haproxy, pass that path via SSL_INC and SSL_LIB :
$ make TARGET=generic \
USE_OPENSSL=1 SSL_INC=$STATICLIBSSL/include SSL_LIB=$STATICLIBSSL/lib
When building with OpenSSL on some systems, you may also need to enable support
for the "libz" library, which is visible if the linker complains about function
"deflateInit()" not being found. In this case, simply append "ADDLIB=-lz" to
the command line.
It is worth mentioning that asynchronous cryptography engines are supported on
OpenSSL 1.1.0 and above. Such engines are used to access hardware cryptography
acceleration that might be present on your system. Due to API changes that
appeared with OpenSSL 3.0 and cause lots of build warnings, engines are not
enabled by default anymore in HAProxy 2.6. It is required to pass USE_ENGINE=1
if they are desired.
4.6) Compression
----------------
HAProxy can compress HTTP responses before delivering them to clients, in order
to save network bandwidth. Two compression options are available. The first one
relies on the libslz library (http://libslz.org) that is embedded in haproxy.
It is enabled by default as it is very fast and does not keep a copy of the
contents in memory. It is possible to disable it, for example for very small
systems, by passing "USE_SLZ=" to the "make" command.
Please note that SLZ will benefit from some CPU-specific instructions like the
availability of the CRC32 extension on some ARM processors. Thus it can further
BUILD: makefile: add a few popular ARMv8 CPU targets This adds the following CPUs to the makefile: - armv81 : modern ARM cores (Cortex A55/A75/A76/A78/X1, Neoverse, Graviton2) - a72 : ARM Cortex-A72 or A73 (e.g. RPi4, Odroid N2, VIM3, AWS Graviton) - a53 : ARM Cortex-A53 or any of its successors in 64-bit mode (e.g. RPi3) - armv8-auto: both older and newer ARMv8 cores, with a minor runtime penalty The reasons for these ones are: - a53 is the common denominator of all of its successors, and does support CRC32 which is used by the gzip compression, that the generic armv8-a does not ; - a72 supports the same features but is an out-of-order one that deserves better optimizations; it's found in a number of high-performance multi-core CPUs mainly oriented towards I/O and network processing (Armada 8040, NXP LX2160A, AWS Graviton), and more recently the Raspberry Pi 4. The A73 found in VIM3 and Odroid-N2 can use the same optimizations ; - armv81 is for generic ARMv8.1-A and above, automatically enables LSE atomics which are way more scalable, and CRC32. This one covers modern ARMv8 cores such as Cortex A55/A75/A76/A77/A78/X1 and the Neoverse family such as found in AWS's Graviton2. The LSE instructions are essential for large numbers of cores (8 and above). - armv8-auto dynamically enables support for LSE extensions when detected while still being compatible with older cores. There is a small performance penalty in doing this (~3%) but a same executable will perform optimally on a wider range of hardware. This should be the best option for distros. It requires gcc-10 or gcc-9.4 and above. When no CPU is specified, GCC version 10.2 and above will automatically implement the wrapper used to detect the LSE extensions.
2021-05-12 07:47:30 +00:00
improve its performance to build with "CPU=native" on the target system, or
"CPU=armv81" (modern systems such as Graviton2 or A55/A75 and beyond),
"CPU=a72" (e.g. for RPi4, or AWS Graviton), "CPU=a53" (e.g. for RPi3), or
"CPU=armv8-auto" (automatic detection with minor runtime penalty).
A second option involves the widely known zlib library, which is very likely
installed on your system. In order to use zlib, simply pass "USE_ZLIB=1" to the
"make" command line, which will also automatically disable SLZ. If the library
is not installed in your default system's path, it is possible to specify the
path to the include files using ZLIB_INC, and the path to the library files
using ZLIB_LIB :
$ make TARGET=generic \
USE_ZLIB=1 ZLIB_INC=/opt/zlib-1.2.11/include ZLIB_LIB=/opt/zlib-1.2.11/lib
Zlib is commonly found on most systems, otherwise updates can be retrieved from
http://www.zlib.net/. It is easy and fast to build, and new versions sometimes
provide better performance so it might be worth using an up-to-date one.
Zlib compresses a bit better than libslz but at the expense of more CPU usage
(about 3.5 times more minimum), and a huge memory usage (~260 kB per compressed
stream). The only valid reason for uzing Zlib instead of SLZ here usually is to
deal with a very limited internet bandwidth while CPU and RAM are abundant so
that the last few percent of compression ratio are worth the invested hardware.
4.7) Lua
--------
Lua is an embedded programming language supported by HAProxy to provide more
advanced scripting capabilities. Only versions 5.3 and above are supported.
In order to enable Lua support, please specify "USE_LUA=1" on the command line.
Some systems provide this library under various names to avoid conflicts with
previous versions. By default, HAProxy looks for "lua5.3", "lua53", "lua". If
your system uses a different naming, you may need to set the library name in
the "LUA_LIB_NAME" variable.
If Lua is not provided on your system, it can be very simply built locally. It
can be downloaded from https://www.lua.org/, extracted and built, for example :
$ cd /opt/lua-5.3.5
$ make linux
The path to the include files and library files may be set using "LUA_INC" and
"LUA_LIB" respectively. For example :
$ make TARGET=generic \
USE_LUA=1 LUA_INC=/opt/lua-5.3.5/src LUA_LIB=/opt/lua-5.3.5/src
4.8) Device detection
---------------------
HAProxy supports several device detection modules relying on third party
products. Some of them may provide free code, others free libs, others free
evaluation licenses. Please read about their respective details in the
following files :
doc/DeviceAtlas-device-detection.txt for DeviceAtlas
doc/51Degrees-device-detection.txt for 51Degrees
doc/WURFL-device-detection.txt for Scientiamobile WURFL
4.9) Miscellaneous
------------------
Some systems have specificities. Usually these specificities are known and/or
detected and properly set for you. If you need to adjust the behaviour, here
are the extra libraries that may be referenced at build time :
- USE_RT=1 build with librt, which is sometimes needed on some systems
when using threads. It is set by default on Linux platforms,
and may be disabled using "USE_RT=" if your system doesn't
have one. You may have to set it as well if you face an error
indicating that clock_gettime() was not found.
- USE_DL=1 build with libdl, which is usually needed for Lua and OpenSSL
on Linux. It is automatically detected and may be disabled
using "USE_DL=", though it should never harm.
- USE_SYSTEMD=1 enables support for the sdnotify features of systemd,
allowing better integration with systemd on Linux systems
which come with it. It is never enabled by default so there
is no need to disable it.
4.10) Common errors
-------------------
Some build errors may happen depending on the options combinations or the
selected target. When facing build errors, if you know that your system is a
bit special or particularly old, start from TARGET=generic, it is easier to
start from there and fix the remaining issues than trying to degrade another
target. Common issues may include:
- clock_gettime() not found
=> your system needs USE_RT=1
- many __sync_<something> errors in many files
=> your gcc is too old, build without threads.
- many openssl errors
=> your OpenSSL version really is too old, do not enable OpenSSL
4.11) QUIC
----------
QUIC is the new transport layer protocol and is required for HTTP/3. This
protocol stack is currently supported as an experimental feature in haproxy on
the frontend side. In order to enable it, use "USE_QUIC=1 USE_OPENSSL=1".
Note that the OpenSSL library is not compatible with QUIC. The preferred option
is to use QUICTLS. This is a fork of OpenSSL with a QUIC-compatible API. Its
repository is available at https://github.com/quictls/openssl. You can use the
following instruction to build a functional QUICTLS.
$ ./config --libdir=lib [--prefix=/opt/quictls]
$ make
$ make install
On a development environment, use SSL_INC and SSL_LIB when building haproxy to
point to the correct cryptographic library. It may be useful to specify QUICTLS
location via rpath for haproxy execution. Example :
$ make TARGET=generic \
USE_QUIC=1 \
USE_OPENSSL=1 SSL_INC=/opt/quictls/include SSL_LIB=/opt/quictls/lib \
LDFLAGS="-Wl,-rpath,/opt/quictls/lib"
5) How to build HAProxy
=======================
This section assumes that you have already read section 2 (basic principles)
and section 3 (build environment). It often refers to section 4 (dependencies).
To build haproxy, you have to choose your target OS amongst the following ones
and assign it to the TARGET variable :
- linux-glibc for Linux kernel 2.6.28 and above
- linux-glibc-legacy for Linux kernel 2.6.28 and above without new features
- linux-musl for Linux kernel 2.6.28 and above with musl libc
- solaris for Solaris 10 and above
- freebsd for FreeBSD 10 and above
- dragonfly for DragonFlyBSD 4.3 and above
- netbsd for NetBSD 8 and above
- osx for Mac OS/X
- openbsd for OpenBSD 6.3 and above
- aix51 for AIX 5.1
- aix52 for AIX 5.2
- aix72-gcc for AIX 7.2 (using gcc)
- cygwin for Cygwin
- haiku for Haiku
- generic for any other OS or version.
- custom to manually adjust every setting
You may also choose your CPU to benefit from some optimizations. This is
particularly important on UltraSparc machines. For this, you can assign
one of the following choices to the CPU variable :
- i686 for intel PentiumPro, Pentium 2 and above, AMD Athlon (32 bits)
- i586 for intel Pentium, AMD K6, VIA C3.
- ultrasparc : Sun UltraSparc I/II/III/IV processor
- power8 : IBM POWER8 processor
- power9 : IBM POWER9 processor
BUILD: makefile: add a few popular ARMv8 CPU targets This adds the following CPUs to the makefile: - armv81 : modern ARM cores (Cortex A55/A75/A76/A78/X1, Neoverse, Graviton2) - a72 : ARM Cortex-A72 or A73 (e.g. RPi4, Odroid N2, VIM3, AWS Graviton) - a53 : ARM Cortex-A53 or any of its successors in 64-bit mode (e.g. RPi3) - armv8-auto: both older and newer ARMv8 cores, with a minor runtime penalty The reasons for these ones are: - a53 is the common denominator of all of its successors, and does support CRC32 which is used by the gzip compression, that the generic armv8-a does not ; - a72 supports the same features but is an out-of-order one that deserves better optimizations; it's found in a number of high-performance multi-core CPUs mainly oriented towards I/O and network processing (Armada 8040, NXP LX2160A, AWS Graviton), and more recently the Raspberry Pi 4. The A73 found in VIM3 and Odroid-N2 can use the same optimizations ; - armv81 is for generic ARMv8.1-A and above, automatically enables LSE atomics which are way more scalable, and CRC32. This one covers modern ARMv8 cores such as Cortex A55/A75/A76/A77/A78/X1 and the Neoverse family such as found in AWS's Graviton2. The LSE instructions are essential for large numbers of cores (8 and above). - armv8-auto dynamically enables support for LSE extensions when detected while still being compatible with older cores. There is a small performance penalty in doing this (~3%) but a same executable will perform optimally on a wider range of hardware. This should be the best option for distros. It requires gcc-10 or gcc-9.4 and above. When no CPU is specified, GCC version 10.2 and above will automatically implement the wrapper used to detect the LSE extensions.
2021-05-12 07:47:30 +00:00
- armv81 : modern ARM cores (Cortex A55/A75/A76/A78/X1, Neoverse, Graviton2)
- a72 : ARM Cortex-A72 or A73 (e.g. RPi4, Odroid N2, AWS Graviton)
- a53 : ARM Cortex-A53 or any of its successors in 64-bit mode (e.g. RPi3)
- armv8-auto : support both older and newer armv8 cores with a minor penalty,
thanks to gcc 10's outline atomics (default with gcc 10.2).
- native : use the build machine's specific processor optimizations. Use with
extreme care, and never in virtualized environments (known to break).
- generic : any other processor or no CPU-specific optimization. (default)
Alternatively, you may just set the CPU_CFLAGS value to the optimal GCC options
for your platform. A second variable named SMALL_OPTS also supports passing a
number of defines and compiler options usually for small systems. For better
clarity it's recommended to pass the options which result in a smaller binary
(like memory limits or -Os) into this variable.
If you are building for a different system than the one you're building on,
this is called "cross-compiling". HAProxy supports cross-compilation pretty
well and tries to ease it by letting you adjust paths to all libraries (please
read section 4 on dependencies for more details). When cross-compiling, you
just need to pass the path to your compiler in the "CC" variable, and the path
to the linker in the "LD" variable. Most of the time, setting the CC variable
is enough since LD points to it by default.
By default the build process runs in quiet mode and hide the details of the
commands that are executed. This allows to more easily catch build warnings
and see what is happening. However it is not convenient at all to observe what
flags are passed to the compiler nor what compiler is involved. Simply append
"V=1" to the "make" command line to switch to verbose mode and display the
details again. It is recommended to use this option when cross-compiling to
verify that the paths are correct and that /usr/include is never invovled.
You may want to build specific target binaries which do not match your native
compiler's target. This is particularly true on 64-bit systems when you want
to build a 32-bit binary. Use the ARCH variable for this purpose. Right now
it only knows about a few x86 variants (i386,i486,i586,i686,x86_64), two
generic ones (32,64) and sets -m32/-m64 as well as -march=<arch> accordingly.
This variable is only used to set ARCH_FLAGS to preset values, so if you know
the arch-specific flags that your system needs, you may prefer to set
ARCH_FLAGS instead. Note that these flags are passed both to the compiler and
to the linker. For example, in order to build a 32-bit binary on an x86_64
Linux system with SSL support without support for compression but when OpenSSL
requires ZLIB anyway :
$ make TARGET=linux-glibc ARCH=i386 USE_OPENSSL=1 ADDLIB=-lz
Recent systems can resolve IPv6 host names using getaddrinfo(). This primitive
is not present in all libcs and does not work in all of them either. Support in
glibc was broken before 2.3. Some embedded libs may not properly work either,
thus, support is disabled by default, meaning that some host names which only
resolve as IPv6 addresses will not resolve and configs might emit an error
during parsing. If you know that your OS libc has reliable support for
getaddrinfo(), you can add USE_GETADDRINFO=1 on the make command line to enable
it. This is the recommended option for most Linux distro packagers since it's
working fine on all recent mainstream distros. It is automatically enabled on
Solaris 8 and above, as it's known to work.
If your system supports PCRE (Perl Compatible Regular Expressions), then you
really should build with libpcre which is between 2 and 10 times faster than
other libc implementations. Regex are used for header processing (deletion,
rewriting, allow, deny). Please see section 4 about dependencies to figure
how to build with PCRE support.
It is possible to add native support for SSL, by passing "USE_OPENSSL=1" on the
make command line. The libssl and libcrypto will automatically be linked with
HAProxy. Some systems also require libz, so if the build fails due to missing
symbols such as deflateInit(), then try again with "ADDLIB=-lz". Please check
section 4 about dependencies for more information on how to build with OpenSSL.
HAProxy can compress HTTP responses to save bandwidth. Please see section 4
about dependencies to see the available libraries and associated options.
By default, the DEBUG_CFLAGS variable is set to '-g' to enable debug symbols.
It is not wise to disable it on uncommon systems, because it's often the only
way to get a usable core when you need one. Otherwise, you can set DEBUG to
'-s' to strip the binary.
If the ERR variable is set to any non-empty value, then -Werror will be added
to the compiler so that any build warning will trigger an error. This is the
recommended way to build when developing, and it is expected that contributed
patches were tested with ERR=1.
The DEBUG variable is used to extend the CFLAGS and is preset to a list of
build-time options that are known for providing significant reliability
improvements and a barely perceptible performance cost. Unless instructed to do
so by some project developers, or trying to save the last ounce of performance,
these options should not be changed. Among the usable ones are:
- -DDEBUG_STRICT: enable some runtime assertions at key places in the code.
The goal is to emit a warning or stop the program if certain expected
conditions are not met, and whose violation will result in a misbehaving
process due to memory corruption or other significant trouble, possibly
caused by an attempt to exploit a bug in the program or a library it relies
on. The option knows 3 values: 0 (disable all such assertions, the default
when the option is not set), 1 (enable all inexpensive assertions), and
2 (enable all assertions even in fast paths). Setting the option with no
value corresponds to 1, which is the recommended value for production.
- -DDEBUG_STRICT_ACTION: indicates how to react to a check violation. There
are 3 types of checks: BUG (condition that is known to have serious
consequences), WARN (warning about a highly suspicious condition which the
process may recover from, but whose unknown cause may also have serious
consequences), CHECK (verification whether a condition that developers now
consider impossible still happens). The variable takes a value from 0 to 3,
that adjusts the behavior on these 3 violations:
BUG WARN CHECK
0 warn warn warn
1 stop warn warn
2 stop stop warn
3 stop stop stop
The default value is 1, which is the best balance for production in that it
will do its best to prevent a known bogus process from running away, but
will let it run if it believes it can recover. Users running the process in
sensitive environments (finance etc) may prefer to run at level 2 to make
sure to stop any detected anomaly before it may have an impact. Level 3
should only be used at the request of developers. In any case, any emitted
warning should be reported to developers.
- -DDEBUG_MEMORY_POOLS: this enables by default extra controls around memory
allocation that will help detect coding errors such as double-frees and
freeing a bad memory location. It will also detect earlier risks of memory
overflows, which may have security implications. The cost is extremely low
(less than 1% increase in memory footprint). This is equivalent to adding
"-dMtag" on the command line. This option is enabled in the default build
options.
- -DDEBUG_DONT_SHARE_POOLS: this will keep separate pools for same-sized
objects of different types. Using this increases the memory usage a little
bit but further reduces the risk of memory management related bugs and will
lead to more accurate traces in case of error. It is equivalent to adding
"-dMno-merge" on the command line. It is not enabled in the default build
options.
- -DDEBUG_POOL_INTEGRITY: this will enable runtime detection and stopping of
a class of bugs known as "use after free", which consists in modifying a
memory area after freeing it while it was reused for something else. This
option is quite powerful but such bugs are fortunately extremely rare, and
it will cause a measurable performance degradation (a few percent). This is
equivalent to adding "-dMcold-first,integrity" on the command line. This
option is not enabled by default but users running development versions on
moderate performance sites in order to participate to reliability testing
are encouraged to use it, in combination with -DDEBUG_DONT_SHARE_POOLS and
-DDEBUG_MEMORY_POOLS, as this could catch dangerous regressions.
As such, for regular production, "-DDEBUG_STRICT -DDEBUG_MEMORY_POOLS" is
recommended. For security sensitive environments, it is recommended to use
"-DDEBUG_STRICT -DDEBUG_STRICT_ACTION=2 -DDEBUG_MEMORY_POOLS \
-DDEBUG_DONT_SHARE_POOLS". For deployments dedicated to testing new versions or
when trying to nail a bug down, use "-DDEBUG_STRICT=2 -DDEBUG_STRICT_ACTION=2 \
-DDEBUG_MEMORY_POOLS -DDEBUG_DONT_SHARE_POOLS -DDEBUG_POOL_INTEGRITY".
The DEP variable is automatically set to the list of include files and also
designates a file that contains the last build options used. It is used during
the build process to compute dependencies and decide whether or not to rebuild
everything (we do rebuild everything when .h files are touched or when build
options change). Sometimes when performing fast build iterations on inline
functions it may be desirable to avoid a full rebuild. Forcing this variable
to be empty will be sufficient to achieve this. This variable must never be
forced to produce final binaries, and must not be used during bisect sessions,
as it will often lead to the wrong commit.
If you need to pass other defines, includes, libraries, etc... then please
check the Makefile to see which ones will be available in your case, and
use/override the USE_* variables from the Makefile.
AIX 5.3 is known to work with the generic target. However, for the binary to
also run on 5.2 or earlier, you need to build with DEFINE="-D_MSGQSUPPORT",
otherwise __fd_select() will be used while not being present in the libc, but
this is easily addressed using the "aix52" target. If you get build errors
because of strange symbols or section mismatches, simply remove -g from
DEBUG_CFLAGS.
Building on AIX 7.2 works fine using the "aix72-gcc" TARGET. It adds two
special CFLAGS to prevent the loading of AIX's xmem.h and var.h. This is done
by defining the corresponding include-guards _H_XMEM and _H_VAR. Without
excluding those header-files the build fails because of redefinition errors.
Furthermore, the atomic library is added to the LDFLAGS to allow for
multithreading via USE_THREAD.
You can easily define your own target with the GNU Makefile. Unknown targets
are processed with no default option except USE_POLL=default. So you can very
well use that property to define your own set of options. USE_POLL and USE_SLZ
can even be disabled by setting them to an empty string. For example :
$ gmake TARGET=tiny USE_POLL="" USE_SLZ="" TARGET_CFLAGS=-fomit-frame-pointer
If you need to pass some defines to the preprocessor or compiler, you may pass
them all in the DEFINE variable. Example:
$ make TARGET=generic DEFINE="-DDEBUG_DONT_SHARE_POOLS -DDEBUG_MEMORY_POOLS"
The ADDINC variable may be used to add some extra include paths; this is
sometimes needed when cross-compiling. Similarly the ADDLIB variable may be
used to specifify extra paths to library files. Example :
$ make TARGET=generic ADDINC=-I/opt/cross/include ADDLIB=-L/opt/cross/lib64
6) How to install HAProxy
=========================
To install haproxy, you can either copy the single resulting binary to the
place you want, or run :
$ sudo make install
If you're packaging it for another system, you can specify its root directory
in the usual DESTDIR variable.
-- end