This document describes installation on all supported operating systems (the Unix/Linux family, including macOS), OpenVMS, and Windows).
- Prerequisites
- Notational Conventions
- Quick Installation Guide
- Configuration Options
- Installation Steps in Detail
- Advanced Build Options
- Troubleshooting
- Notes
To install OpenSSL, you will need:
- A "make" implementation
- Perl 5 with core modules (please read NOTES-PERL.md)
- The Perl module
Text::Template
(please read NOTES-PERL.md) - an ANSI C compiler
- a development environment in the form of development libraries and C header files
- a supported operating system
For additional platform specific requirements, solutions to specific issues and other details, please read one of these:
- Notes for UNIX-like platforms
- Notes for Android platforms
- Notes for Windows platforms
- Notes for the DOS platform with DJGPP
- Notes for the OpenVMS platform
- Notes on Perl
- Notes on Valgrind
Throughout this document, we use the following conventions.
Any line starting with a dollar sign is a command line.
$ command
The dollar sign indicates the shell prompt and is not to be entered as part of the command.
Several words in curly braces separated by pipe characters indicate a mandatory choice, to be replaced with one of the given words. For example, the line
$ echo { WORD1 | WORD2 | WORD3 }
represents one of the following three commands
$ echo WORD1
- or -
$ echo WORD2
- or -
$ echo WORD3
One or several words in square brackets separated by pipe characters denote an optional choice. It is similar to the mandatory choice, but it can also be omitted entirely.
So the line
$ echo [ WORD1 | WORD2 | WORD3 ]
represents one of the four commands
$ echo WORD1
- or -
$ echo WORD2
- or -
$ echo WORD3
- or -
$ echo
Mandatory arguments are enclosed in double curly braces. A simple example would be
$ type {{ filename }}
which is to be understood to use the command type
on some file name
determined by the user.
Optional Arguments are enclosed in double square brackets.
[[ options ]]
Note that the notation assumes spaces around {
, }
, [
, ]
, {{
, }}
and
[[
, ]]
. This is to differentiate from OpenVMS directory
specifications, which also use [ and ], but without spaces.
If you just want to get OpenSSL installed without bothering too much about the details, here is the short version of how to build and install OpenSSL. If any of the following steps fails, please consult the Installation in Detail section below.
Use the following commands to configure, build and test OpenSSL. The testing is optional, but recommended if you intend to install OpenSSL for production use.
$ ./Configure
$ make
$ make test
Use the following commands to build OpenSSL:
$ perl Configure
$ mms
$ mms test
If you are using Visual Studio, open a Developer Command Prompt and issue the following commands to build OpenSSL.
$ perl Configure
$ nmake
$ nmake test
As mentioned in the Choices section, you need to pick one of the four Configure targets in the first command.
Most likely you will be using the VC-WIN64A
target for 64bit Windows
binaries (AMD64) or VC-WIN32
for 32bit Windows binaries (X86).
The other two options are VC-WIN64I
(Intel IA64, Itanium) and
VC-CE
(Windows CE) are rather uncommon nowadays.
The following commands will install OpenSSL to a default system location.
Danger Zone: even if you are impatient, please read the following two paragraphs carefully before you install OpenSSL.
For security reasons the default system location is by default not writable for unprivileged users. So for the final installation step administrative privileges are required. The default system location and the procedure to obtain administrative privileges depends on the operating system. It is recommended to compile and test OpenSSL with normal user privileges and use administrative privileges only for the final installation step.
On some platforms OpenSSL is preinstalled as part of the Operating System. In this case it is highly recommended not to overwrite the system versions, because other applications or libraries might depend on it. To avoid breaking other applications, install your copy of OpenSSL to a different location which is not in the global search path for system libraries.
Finally, if you plan on using the FIPS module, you need to read the Post-installation Notes further down.
Depending on your distribution, you need to run the following command as
root user or prepend sudo
to the command:
$ make install
By default, OpenSSL will be installed to
/usr/local
More precisely, the files will be installed into the subdirectories
/usr/local/bin
/usr/local/lib
/usr/local/include
...
depending on the file type, as it is custom on Unix-like operating systems.
Use the following command to install OpenSSL.
$ mms install
By default, OpenSSL will be installed to
SYS$COMMON:[OPENSSL]
If you are using Visual Studio, open the Developer Command Prompt elevated and issue the following command.
$ nmake install
The easiest way to elevate the Command Prompt is to press and hold down
the both the <CTRL>
and <SHIFT>
key while clicking the menu item in the
task menu.
The default installation location is
C:\Program Files\OpenSSL
for native binaries, or
C:\Program Files (x86)\OpenSSL
for 32bit binaries on 64bit Windows (WOW64).
To install OpenSSL to a different location (for example into your home
directory for testing purposes) run Configure
as shown in the following
examples.
The options --prefix
and --openssldir
are explained in further detail in
Directories below, and the values used here are mere examples.
On Unix:
$ ./Configure --prefix=/opt/openssl --openssldir=/usr/local/ssl
On OpenVMS:
$ perl Configure --prefix=PROGRAM:[INSTALLS] --openssldir=SYS$MANAGER:[OPENSSL]
Note: if you do add options to the configuration command, please make sure
you've read more than just this Quick Start, such as relevant NOTES-*
files,
the options outline below, as configuration options may change the outcome
in otherwise unexpected ways.
There are several options to ./Configure
to customize the build (note that
for Windows, the defaults for --prefix
and --openssldir
depend on what
configuration is used and what Windows implementation OpenSSL is built on.
For more information, see the Notes for Windows platforms.
--api=x.y[.z]
Build the OpenSSL libraries to support the API for the specified version. If no-deprecated is also given, don't build with support for deprecated APIs in or below the specified version number. For example, addding
--api=1.1.0 no-deprecated
will remove support for all APIs that were deprecated in OpenSSL version
1.1.0 or below. This is a rather specialized option for developers.
If you just intend to remove all deprecated APIs up to the current version
entirely, just specify no-deprecated.
If --api
isn't given, it defaults to the current (minor) OpenSSL version.
--cross-compile-prefix=<PREFIX>
The <PREFIX>
to include in front of commands for your toolchain.
It is likely to have to end with dash, e.g. a-b-c-
would invoke GNU compiler
as a-b-c-gcc
, etc. Unfortunately cross-compiling is too case-specific to put
together one-size-fits-all instructions. You might have to pass more flags or
set up environment variables to actually make it work. Android and iOS cases
are discussed in corresponding Configurations/15-*.conf
files. But there are
cases when this option alone is sufficient. For example to build the mingw64
target on Linux --cross-compile-prefix=x86_64-w64-mingw32-
works. Naturally
provided that mingw packages are installed. Today Debian and Ubuntu users
have option to install a number of prepackaged cross-compilers along with
corresponding run-time and development packages for "alien" hardware. To give
another example --cross-compile-prefix=mipsel-linux-gnu-
suffices in such
case.
For cross compilation, you must configure manually.
Also, note that --openssldir
refers to target's file system, not one you are
building on.
--debug
Build OpenSSL with debugging symbols and zero optimization level.
--release
Build OpenSSL without debugging symbols. This is the default.
--libdir=DIR
The name of the directory under the top of the installation directory tree
(see the --prefix
option) where libraries will be installed. By default
this is lib/
. Note that on Windows only static libraries (*.lib
) will
be stored in this location. Shared libraries (*.dll
) will always be
installed to the bin/
directory.
--openssldir=DIR
Directory for OpenSSL configuration files, and also the default certificate and key store. Defaults are:
Unix: /usr/local/ssl
Windows: C:\Program Files\Common Files\SSL
OpenVMS: SYS$COMMON:[OPENSSL-COMMON]
For 32bit Windows applications on Windows 64bit (WOW64), always replace
C:\Program Files
by C:\Program Files (x86)
.
--prefix=DIR
The top of the installation directory tree. Defaults are:
Unix: /usr/local
Windows: C:\Program Files\OpenSSL
OpenVMS: SYS$COMMON:[OPENSSL]
--strict-warnings
This is a developer flag that switches on various compiler options recommended for OpenSSL development. It only works when using gcc or clang as the compiler. If you are developing a patch for OpenSSL then it is recommended that you use this option where possible.
--with-zlib-include=DIR
The directory for the location of the zlib include file. This option is only necessary if zlib is used and the include file is not already on the system include path.
--with-zlib-lib=LIB
On Unix: this is the directory containing the zlib library. If not provided the system library path will be used.
On Windows: this is the filename of the zlib library (with or
without a path). This flag must be provided if the
zlib-dynamic option is not also used. If zlib-dynamic
is used
then this flag is optional and defaults to ZLIB1
if not provided.
On VMS: this is the filename of the zlib library (with or without a path).
This flag is optional and if not provided then GNV$LIBZSHR
, GNV$LIBZSHR32
or GNV$LIBZSHR64
is used by default depending on the pointer size chosen.
--with-rand-seed=seed1[,seed2,...]
A comma separated list of seeding methods which will be tried by OpenSSL in order to obtain random input (a.k.a "entropy") for seeding its cryptographically secure random number generator (CSPRNG). The current seeding methods are:
Use a trusted operating system entropy source. This is the default method if such an entropy source exists.
Use the getrandom(2) or equivalent system call.
Use the first device from the DEVRANDOM
list which can be opened to read
random bytes. The DEVRANDOM
preprocessor constant expands to
"/dev/urandom","/dev/random","/dev/srandom"
on most unix-ish operating systems.
Check for an entropy generating daemon. This source is ignored by the FIPS provider.
Use the RDSEED
or RDRAND
command if provided by the CPU.
Use librandom (not implemented yet). This source is ignored by the FIPS provider.
Disable automatic seeding. This is the default on some operating systems where no suitable entropy source exists, or no support for it is implemented yet. This option is ignored by the FIPS provider.
For more information, see the section Notes on random number generation at the end of this document.
--fips-key=value
As part of its self-test validation, the FIPS module must verify itself by performing a SHA-256 HMAC computation on itself. The default key is the SHA256 value of "the holy handgrenade of antioch" and is sufficient for meeting the FIPS requirements.
To change the key to a different value, use this flag. The value should be a hex string no more than 64 characters.
Feature options always come in pairs, an option to enable feature
xxxx
, and an option to disable it:
[ enable-xxxx | no-xxxx ]
Whether a feature is enabled or disabled by default, depends on the feature.
In the following list, always the non-default variant is documented: if
feature xxxx
is disabled by default then enable-xxxx
is documented and
if feature xxxx
is enabled by default then no-xxxx
is documented.
Don't build the AFALG engine.
This option will be forced on a platform that does not support AFALG.
Build with Kernel TLS support.
This option will enable the use of the Kernel TLS data-path, which can improve performance and allow for the use of sendfile and splice system calls on TLS sockets. The Kernel may use TLS accelerators if any are available on the system. This option will be forced off on systems that do not support the Kernel TLS data-path.
Build with the Address sanitiser.
This is a developer option only. It may not work on all platforms and should never be used in production environments. It will only work when used with gcc or clang and should be used in conjunction with the no-shared option.
Do not build support for Automated Cryptographic Validation Protocol (ACVP) tests.
This is required for FIPS validation purposes. Certain ACVP tests require access to algorithm internals that are not normally accessible. Additional information related to ACVP can be found at https://github.com/usnistgov/ACVP.
Do not use assembler code.
This should be viewed as debugging/troubleshooting option rather than for production use. On some platforms a small amount of assembler code may still be used even with this option.
Do not build support for async operations.
Don't automatically load all supported ciphers and digests.
Typically OpenSSL will make available all of its supported ciphers and digests.
For a statically linked application this may be undesirable if small executable
size is an objective. This only affects libcrypto. Ciphers and digests will
have to be loaded manually using EVP_add_cipher()
and EVP_add_digest()
if this option is used. This option will force a non-shared build.
Don't automatically load all libcrypto/libssl error strings.
Typically OpenSSL will automatically load human readable error strings. For a statically linked application this may be undesirable if small executable size is an objective.
Don't automatically load the default openssl.cnf
file.
Typically OpenSSL will automatically load a system config file which configures default SSL options.
While testing, generate C++ buildtest files that simply check that the public OpenSSL header files are usable standalone with C++.
Enabling this option demands extra care. For any compiler flag given directly
as configuration option, you must ensure that it's valid for both the C and
the C++ compiler. If not, the C++ build test will most likely break. As an
alternative, you can use the language specific variables, CFLAGS
and CXXFLAGS
.
Build only some minimal set of features. This is a developer option used internally for CI build tests of the project.
Never cache algorithms when they are fetched from a provider. Normally, a provider indicates if the algorithms it supplies can be cached or not. Using this option will reduce run-time memory usage but it also introduces a significant performance penalty. This option is primarily designed to help with detecting incorrect reference counting.
Don't build the CAPI engine.
This option will be forced if on a platform that does not support CAPI.
Don't build support for Certificate Management Protocol (CMP) and Certificate Request Message Format (CRMF).
Don't build support for Cryptographic Message Syntax (CMS).
Don't build support for SSL/TLS compression.
If this option is enabled (the default), then compression will only work if
the zlib or zlib-dynamic
options are also chosen.
This now only enables the failed-malloc
feature.
This is a no-op; the project uses the compiler's address/leak sanitizer instead.
Don't build support for Certificate Transparency (CT).
Don't build with support for deprecated APIs up until and including the version
given with --api
(or the current version, if --api
wasn't specified).
Don't build support for datagram based BIOs.
Selecting this option will also force the disabling of DTLS.
Don't build support for loading Dynamic Shared Objects (DSO)
Build the /dev/crypto
engine.
This option is automatically selected on the BSD platform, in which case it can
be disabled with no-devcryptoeng
.
Don't build the dynamically loaded engines.
This only has an effect in a shared build.
Don't build support for Elliptic Curves.
Don't build support for binary Elliptic Curves
Enable support for optimised implementations of some commonly used NIST elliptic curves.
This option is only supported on platforms:
- with little-endian storage of non-byte types
- that tolerate misaligned memory references
- where the compiler:
- supports the non-standard type
__uint128_t
- defines the built-in macro
__SIZEOF_INT128__
- supports the non-standard type
Build support for gathering entropy from the Entropy Gathering Daemon (EGD).
Don't build support for loading engines.
Don't compile in any error strings.
Enable building of integration with external test suites.
This is a developer option and may not work on all platforms. The following external test suites are currently supported:
- GOST engine test suite
- Python PYCA/Cryptography test suite
- krb5 test suite
See the file test/README-external.md for further details.
Don't compile in filename and line number information (e.g. for errors and memory allocation).
Don't compile the FIPS provider
Don't perform FIPS module run-time checks related to enforcement of security parameters such as minimum security strength of keys.
Build with support for fuzzing using either libfuzzer or AFL.
These are developer options only. They may not work on all platforms and should never be used in production environments.
See the file fuzz/README.md for further details.
Don't build support for GOST based ciphersuites.
Note that if this feature is enabled then GOST ciphersuites are only available if the GOST algorithms are also available through loading an externally supplied engine.
Don't build the legacy provider.
Disabling this also disables the legacy algorithms: MD2 (already disabled by default).
Don't generate dependencies.
Don't build any dynamically loadable engines.
This also implies no-dynamic-engine
.
Don't build support for writing multiple records in one go in libssl
Note: this is a different capability to the pipelining functionality.
Don't build support for the Next Protocol Negotiation (NPN) TLS extension.
Don't build support for Online Certificate Status Protocol (OCSP).
Don't build the padlock engine.
As synonym for no-padlockeng
. Deprecated and should not be used.
Don't build with support for Position Independent Code.
Don't pin the shared libraries.
By default OpenSSL will attempt to stay in memory until the process exits.
This is so that libcrypto and libssl can be properly cleaned up automatically
via an atexit()
handler. The handler is registered by libcrypto and cleans
up both libraries. On some platforms the atexit()
handler will run on unload of
libcrypto (if it has been dynamically loaded) rather than at process exit. This
option can be used to stop OpenSSL from attempting to stay in memory until the
process exits. This could lead to crashes if either libcrypto or libssl have
already been unloaded at the point that the atexit handler is invoked, e.g. on a
platform which calls atexit()
on unload of the library, and libssl is unloaded
before libcrypto then a crash is likely to happen. Applications can suppress
running of the atexit()
handler at run time by using the
OPENSSL_INIT_NO_ATEXIT
option to OPENSSL_init_crypto()
.
See the man page for it for further details.
Don't use POSIX IO capabilities.
Don't build support for Pre-Shared Key based ciphersuites.
Don't use hardware RDRAND capabilities.
Don't build support for RFC3779, "X.509 Extensions for IP Addresses and AS Identifiers".
Build support for Stream Control Transmission Protocol (SCTP).
Do not create shared libraries, only static ones.
See Notes on shared libraries below.
Don't build support for socket BIOs.
Don't build support for Secure Remote Password (SRP) protocol or SRP based ciphersuites.
Don't build Secure Real-Time Transport Protocol (SRTP) support.
Exclude SSE2 code paths from 32-bit x86 assembly modules.
Normally SSE2 extension is detected at run-time, but the decision whether or not
the machine code will be executed is taken solely on CPU capability vector. This
means that if you happen to run OS kernel which does not support SSE2 extension
on Intel P4 processor, then your application might be exposed to "illegal
instruction" exception. There might be a way to enable support in kernel, e.g.
FreeBSD kernel can be compiled with CPU_ENABLE_SSE
, and there is a way to
disengage SSE2 code paths upon application start-up, but if you aim for wider
"audience" running such kernel, consider no-sse2
. Both the 386
and no-asm
options imply no-sse2
.
Build with the SSL Trace capabilities.
This adds the -trace
option to s_client
and s_server
.
Don't build the statically linked engines.
This only has an impact when not built "shared".
Don't use anything from the C header file stdio.h
that makes use of the FILE
type. Only libcrypto and libssl can be built in this way. Using this option will
suppress building the command line applications. Additionally, since the OpenSSL
tests also use the command line applications, the tests will also be skipped.
Don't build test programs or run any tests.
Don't build with support for multi-threaded applications.
Build with support for multi-threaded applications. Most platforms will enable this by default. However, if on a platform where this is not the case then this will usually require additional system-dependent options!
See Notes on multi-threading below.
Build with support for the integrated tracing api.
See manual pages OSSL_trace_set_channel(3) and OSSL_trace_enabled(3) for details.
Don't build Time Stamping (TS) Authority support.
Build with the Undefined Behaviour sanitiser (UBSAN).
This is a developer option only. It may not work on all platforms and should
never be used in production environments. It will only work when used with
gcc or clang and should be used in conjunction with the -DPEDANTIC
option
(or the --strict-warnings
option).
Don't build with the User Interface (UI) console method
The User Interface console method enables text based console prompts.
Enable additional unit test APIs.
This should not typically be used in production deployments.
Don't build support for UPLINK interface.
Build support for SSL/TLS ciphers that are considered "weak"
Enabling this includes for example the RC4 based ciphersuites.
Build with support for zlib compression/decompression.
Like the zlib option, but has OpenSSL load the zlib library dynamically when needed.
This is only supported on systems where loading of shared libraries is supported.
In 32-bit x86 builds, use the 80386 instruction set only in assembly modules
The default x86 code is more efficient, but requires at least an 486 processor. Note: This doesn't affect compiler generated code, so this option needs to be accompanied by a corresponding compiler-specific option.
no-{ssl|ssl3|tls|tls1|tls1_1|tls1_2|tls1_3|dtls|dtls1|dtls1_2}
Don't build support for negotiating the specified SSL/TLS protocol.
If no-tls
is selected then all of tls1
, tls1_1
, tls1_2
and tls1_3
are disabled.
Similarly no-dtls
will disable dtls1
and dtls1_2
. The no-ssl
option is
synonymous with no-ssl3
. Note this only affects version negotiation.
OpenSSL will still provide the methods for applications to explicitly select
the individual protocol versions.
no-{ssl|ssl3|tls|tls1|tls1_1|tls1_2|tls1_3|dtls|dtls1|dtls1_2}-method
Analogous to no-{protocol}
but in addition do not build the methods for
applications to explicitly select individual protocol versions. Note that there
is no no-tls1_3-method
option because there is no application method for
TLSv1.3.
Using individual protocol methods directly is deprecated. Applications should
use TLS_method()
instead.
enable-{md2|rc5}
Build with support for the specified algorithm.
no-{aria|bf|blake2|camellia|cast|chacha|cmac|
des|dh|dsa|ecdh|ecdsa|idea|md4|mdc2|ocb|
poly1305|rc2|rc4|rmd160|scrypt|seed|
siphash|siv|sm2|sm3|sm4|whirlpool}
Build without support for the specified algorithm.
The ripemd
algorithm is deprecated and if used is synonymous with rmd160
.
-Dxxx, -Ixxx, -Wp, -lxxx, -Lxxx, -Wl, -rpath, -R, -framework, -static
These system specific options will be recognised and passed through to the compiler to allow you to define preprocessor symbols, specify additional libraries, library directories or other compiler options. It might be worth noting that some compilers generate code specifically for processor the compiler currently executes on. This is not necessarily what you might have in mind, since it might be unsuitable for execution on other, typically older, processor. Consult your compiler documentation.
Take note of the Environment Variables documentation below and how these flags interact with those variables.
-xxx, +xxx, /xxx
Additional options that are not otherwise recognised are passed through as
they are to the compiler as well. Unix-style options beginning with a
-
or +
and Windows-style options beginning with a /
are recognized.
Again, consult your compiler documentation.
If the option contains arguments separated by spaces, then the URL-style
notation %20
can be used for the space character in order to avoid having
to quote the option. For example, -opt%20arg
gets expanded to -opt arg
.
In fact, any ASCII character can be encoded as %xx using its hexadecimal
encoding.
Take note of the Environment Variables documentation below and how these flags interact with those variables.
VAR=value
Assign the given value to the environment variable VAR
for Configure
.
These work just like normal environment variable assignments, but are supported on all platforms and are confined to the configuration scripts only. These assignments override the corresponding value in the inherited environment, if there is one.
The following variables are used as "make
variables" and can be used as an
alternative to giving preprocessor, compiler and linker options directly as
configuration. The following variables are supported:
AR The static library archiver.
ARFLAGS Flags for the static library archiver.
AS The assembler compiler.
ASFLAGS Flags for the assembler compiler.
CC The C compiler.
CFLAGS Flags for the C compiler.
CXX The C++ compiler.
CXXFLAGS Flags for the C++ compiler.
CPP The C/C++ preprocessor.
CPPFLAGS Flags for the C/C++ preprocessor.
CPPDEFINES List of CPP macro definitions, separated
by a platform specific character (':' or
space for Unix, ';' for Windows, ',' for
VMS). This can be used instead of using
-D (or what corresponds to that on your
compiler) in CPPFLAGS.
CPPINCLUDES List of CPP inclusion directories, separated
the same way as for CPPDEFINES. This can
be used instead of -I (or what corresponds
to that on your compiler) in CPPFLAGS.
HASHBANGPERL Perl invocation to be inserted after '#!'
in public perl scripts (only relevant on
Unix).
LD The program linker (not used on Unix, $(CC)
is used there).
LDFLAGS Flags for the shared library, DSO and
program linker.
LDLIBS Extra libraries to use when linking.
Takes the form of a space separated list
of library specifications on Unix and
Windows, and as a comma separated list of
libraries on VMS.
RANLIB The library archive indexer.
RC The Windows resource compiler.
RCFLAGS Flags for the Windows resource compiler.
RM The command to remove files and directories.
These cannot be mixed with compiling/linking flags given on the command line. In other words, something like this isn't permitted.
$ ./Configure -DFOO CPPFLAGS=-DBAR -DCOOKIE
Backward compatibility note:
To be compatible with older configuration scripts, the environment variables are ignored if compiling/linking flags are given on the command line, except for the following:
AR, CC, CXX, CROSS_COMPILE, HASHBANGPERL, PERL, RANLIB, RC, and WINDRES
For example, the following command will not see -DBAR
:
$ CPPFLAGS=-DBAR ./Configure -DCOOKIE
However, the following will see both set variables:
$ CC=gcc CROSS_COMPILE=x86_64-w64-mingw32- ./Configure -DCOOKIE
If CC
is set, it is advisable to also set CXX
to ensure both the C and C++
compiler are in the same "family". This becomes relevant with
enable-external-tests
and enable-buildtest-c++
.
reconf
reconfigure
Reconfigure from earlier data.
This fetches the previous command line options and environment from data
saved in configdata.pm
and runs the configuration process again, using
these options and environment. Note: NO other option is permitted together
with reconf
. Note: The original configuration saves away values for ALL
environment variables that were used, and if they weren't defined, they are
still saved away with information that they weren't originally defined.
This information takes precedence over environment variables that are
defined when reconfiguring.
The configuration script itself will say very little, and finishes by
creating configdata.pm
. This perl module can be loaded by other scripts
to find all the configuration data, and it can also be used as a script to
display all sorts of configuration data in a human readable form.
For more information, please do:
$ ./configdata.pm --help # Unix
or
$ perl configdata.pm --help # Windows and VMS
On some platform a config
script is available which attempts to guess
your operating system (and compiler, if necessary) and calls the Configure
Perl script with appropriate target based on its guess. Further options can
be supplied to the config
script, which will be passed on to the Configure
script.
$ ./Configure [[ options ]]
$ perl Configure [[ options ]]
$ perl Configure [[ options ]]
OpenSSL knows about a range of different operating system, hardware and compiler combinations. To see the ones it knows about, run
$ ./Configure LIST # Unix
or
$ perl Configure LIST # All other platforms
For the remainder of this text, the Unix form will be used in all examples. Please use the appropriate form for your platform.
Pick a suitable name from the list that matches your system. For most
operating systems there is a choice between using cc or gcc.
When you have identified your system (and if necessary compiler) use this
name as the argument to Configure
. For example, a linux-elf
user would
run:
$ ./Configure linux-elf [[ options ]]
If your system isn't listed, you will have to create a configuration
file named Configurations/{{ something }}.conf
and add the correct
configuration for your system. See the available configs as examples
and read Configurations/README.md and
Configurations/README-design.md
for more information.
The generic configurations cc
or gcc
should usually work on 32 bit
Unix-like systems.
Configure
creates a build file (Makefile
on Unix, makefile
on Windows
and descrip.mms
on OpenVMS) from a suitable template in Configurations/
,
and defines various macros in include/openssl/configuration.h
(generated
from include/openssl/configuration.h.in
.
OpenSSL can be configured to build in a build directory separate from the source code directory. It's done by placing yourself in some other directory and invoking the configuration commands from there.
$ mkdir /var/tmp/openssl-build
$ cd /var/tmp/openssl-build
$ /PATH/TO/OPENSSL/SOURCE/Configure [[ options ]]
$ set default sys$login:
$ create/dir [.tmp.openssl-build]
$ set default [.tmp.openssl-build]
$ perl D:[PATH.TO.OPENSSL.SOURCE]Configure [[ options ]]
$ C:
$ mkdir \temp-openssl
$ cd \temp-openssl
$ perl d:\PATH\TO\OPENSSL\SOURCE\Configure [[ options ]]
Paths can be relative just as well as absolute. Configure
will do its best
to translate them to relative paths whenever possible.
Build OpenSSL by running:
$ make # Unix
$ mms ! (or mmk) OpenVMS
$ nmake # Windows
This will build the OpenSSL libraries (libcrypto.a
and libssl.a
on
Unix, corresponding on other platforms) and the OpenSSL binary
(openssl
). The libraries will be built in the top-level directory,
and the binary will be in the apps/
subdirectory.
If the build fails, take a look at the Build Failures subsection of the Troubleshooting section.
After a successful build, and before installing, the libraries should be tested. Run:
$ make test # Unix
$ mms test ! OpenVMS
$ nmake test # Windows
Warning: you MUST run the tests from an unprivileged account (or disable your privileges temporarily if your platform allows it).
See test/README.md for further details how run tests.
See test/README-dev.md for guidelines on adding tests.
If everything tests ok, install OpenSSL with
$ make install # Unix
$ mms install ! OpenVMS
$ nmake install # Windows
Note that in order to perform the install step above you need to have appropriate permissions to write to the installation directory.
The above commands will install all the software components in this
directory tree under <PREFIX>
(the directory given with --prefix
or
its default):
bin/ Contains the openssl binary and a few other
utility scripts.
include/openssl
Contains the header files needed if you want
to build your own programs that use libcrypto
or libssl.
lib Contains the OpenSSL library files.
lib/engines Contains the OpenSSL dynamically loadable engines.
share/man/man1 Contains the OpenSSL command line man-pages.
share/man/man3 Contains the OpenSSL library calls man-pages.
share/man/man5 Contains the OpenSSL configuration format man-pages.
share/man/man7 Contains the OpenSSL other misc man-pages.
share/doc/openssl/html/man1
share/doc/openssl/html/man3
share/doc/openssl/html/man5
share/doc/openssl/html/man7
Contains the HTML rendition of the man-pages.
'arch' is replaced with the architecture name, ALPHA
or IA64
,
'sover' is replaced with the shared library version (0101
for 1.1), and
'pz' is replaced with the pointer size OpenSSL was built with:
[.EXE.'arch'] Contains the openssl binary.
[.EXE] Contains a few utility scripts.
[.include.openssl]
Contains the header files needed if you want
to build your own programs that use libcrypto
or libssl.
[.LIB.'arch'] Contains the OpenSSL library files.
[.ENGINES'sover''pz'.'arch']
Contains the OpenSSL dynamically loadable engines.
[.SYS$STARTUP] Contains startup, login and shutdown scripts.
These define appropriate logical names and
command symbols.
[.SYSTEST] Contains the installation verification procedure.
[.HTML] Contains the HTML rendition of the manual pages.
Additionally, install will add the following directories under
OPENSSLDIR (the directory given with --openssldir
or its default)
for you convenience:
certs Initially empty, this is the default location
for certificate files.
private Initially empty, this is the default location
for private key files.
misc Various scripts.
The installation directory should be appropriately protected to ensure unprivileged users cannot make changes to OpenSSL binaries or files, or install engines. If you already have a pre-installed version of OpenSSL as part of your Operating System it is recommended that you do not overwrite the system version and instead install to somewhere else.
Package builders who want to configure the library for standard locations, but have the package installed somewhere else so that it can easily be packaged, can use
$ make DESTDIR=/tmp/package-root install # Unix
$ mms/macro="DESTDIR=TMP:[PACKAGE-ROOT]" install ! OpenVMS
The specified destination directory will be prepended to all installation target paths.
Starting with version 1.1.0, OpenSSL hides a number of structures that were previously open. This includes all internal libssl structures and a number of EVP types. Accessor functions have been added to allow controlled access to the structures' data.
This means that some software needs to be rewritten to adapt to the new ways of doing things. This often amounts to allocating an instance of a structure explicitly where you could previously allocate them on the stack as automatic variables, and using the provided accessor functions where you would previously access a structure's field directly.
Some APIs have changed as well. However, older APIs have been preserved when possible.
With the default OpenSSL installation comes a FIPS provider module, which needs some post-installation attention, without which it will not be usable. This involves using the following command:
$ openssl fipsinstall
See the openssl-fipsinstall(1) manual for details and examples.
A number of environment variables can be used to provide additional control
over the build process. Typically these should be defined prior to running
Configure
. Not all environment variables are relevant to all platforms.
AR
The name of the ar executable to use.
BUILDFILE
Use a different build file name than the platform default
("Makefile" on Unix-like platforms, "makefile" on native Windows,
"descrip.mms" on OpenVMS). This requires that there is a
corresponding build file template.
See [Configurations/README.md](Configurations/README.md)
for further information.
CC
The compiler to use. Configure will attempt to pick a default
compiler for your platform but this choice can be overridden
using this variable. Set it to the compiler executable you wish
to use, e.g. gcc or clang.
CROSS_COMPILE
This environment variable has the same meaning as for the
"--cross-compile-prefix" Configure flag described above. If both
are set then the Configure flag takes precedence.
NM
The name of the nm executable to use.
OPENSSL_LOCAL_CONFIG_DIR
OpenSSL comes with a database of information about how it
should be built on different platforms as well as build file
templates for those platforms. The database is comprised of
".conf" files in the Configurations directory. The build
file templates reside there as well as ".tmpl" files. See the
file [Configurations/README.md](Configurations/README.md)
for further information about the format of ".conf" files
as well as information on the ".tmpl" files.
In addition to the standard ".conf" and ".tmpl" files, it is
possible to create your own ".conf" and ".tmpl" files and
store them locally, outside the OpenSSL source tree.
This environment variable can be set to the directory where
these files are held and will be considered by Configure
before it looks in the standard directories.
PERL
The name of the Perl executable to use when building OpenSSL.
Only needed if builing should use a different Perl executable
than what is used to run the Configure script.
HASHBANGPERL
The command string for the Perl executable to insert in the
#! line of perl scripts that will be publicly installed.
Default: /usr/bin/env perl
Note: the value of this variable is added to the same scripts
on all platforms, but it's only relevant on Unix-like platforms.
RC
The name of the rc executable to use. The default will be as
defined for the target platform in the ".conf" file. If not
defined then "windres" will be used. The WINDRES environment
variable is synonymous to this. If both are defined then RC
takes precedence.
RANLIB
The name of the ranlib executable to use.
WINDRES
See RC.
The Configure
script generates a Makefile in a format relevant to the specific
platform. The Makefiles provide a number of targets that can be used. Not all
targets may be available on all platforms. Only the most common targets are
described here. Examine the Makefiles themselves for the full list.
all
The target to build all the software components and
documentation.
build_sw
Build all the software components.
THIS IS THE DEFAULT TARGET.
build_docs
Build all documentation components.
clean
Remove all build artefacts and return the directory to a "clean"
state.
depend
Rebuild the dependencies in the Makefiles. This is a legacy
option that no longer needs to be used since OpenSSL 1.1.0.
install
Install all OpenSSL components.
install_sw
Only install the OpenSSL software components.
install_docs
Only install the OpenSSL documentation components.
install_man_docs
Only install the OpenSSL man pages (Unix only).
install_html_docs
Only install the OpenSSL HTML documentation.
install_fips
Install the FIPS provider module configuration file.
list-tests
Prints a list of all the self test names.
test
Build and run the OpenSSL self tests.
uninstall
Uninstall all OpenSSL components.
reconfigure
reconf
Re-run the configuration process, as exactly as the last time
as possible.
update
This is a developer option. If you are developing a patch for
OpenSSL you may need to use this if you want to update
automatically generated files; add new error codes or add new
(or change the visibility of) public API functions. (Unix only).
You can specify a set of tests to be performed
using the make
variable TESTS
.
See the section Running Selected Tests of test/README.md.
The ./Configure
script tries hard to guess your operating system, but in some
cases it does not succeed. You will see a message like the following:
$ ./Configure
Operating system: x86-whatever-minix
This system (minix) is not supported. See file INSTALL.md for details.
Even if the automatic target selection by the ./Configure
script fails,
chances are that you still might find a suitable target in the Configurations
directory, which you can supply to the ./Configure
command,
possibly after some adjustment.
The Configurations/
directory contains a lot of examples of such targets.
The main configuration file is 10-main.conf, which contains all targets that
are officially supported by the OpenSSL team. Other configuration files contain
targets contributed by other OpenSSL users. The list of targets can be found in
a Perl list my %targets = ( ... )
.
my %targets = (
...
"target-name" => {
inherit_from => [ "base-target" ],
CC => "...",
cflags => add("..."),
asm_arch => '...',
perlasm_scheme => "...",
},
...
)
If you call ./Configure
without arguments, it will give you a list of all
known targets. Using grep
, you can lookup the target definition in the
Configurations/
directory. For example the android-x86_64
can be found in
Configurations/15-android.conf.
The directory contains two README files, which explain the general syntax and design of the configuration files.
If you need further help, try to search the openssl-users mailing list or the GitHub Issues for existing solutions. If you don't find anything, you can raise an issue to ask a question yourself.
More about our support resources can be found in the SUPPORT file.
If the ./Configure
or ./Configure
command fails with an error message,
read the error message carefully and try to figure out whether you made
a mistake (e.g., by providing a wrong option), or whether the script is
working incorrectly. If you think you encountered a bug, please
raise an issue on GitHub to file a bug report.
Along with a short description of the bug, please provide the complete configure command line and the relevant output including the error message.
Note: To make the output readable, pleace add a 'code fence' (three backquotes
```
on a separate line) before and after your output:
```
./Configure [your arguments...]
[output...]
```
If the build fails, look carefully at the output. Try to locate and understand the error message. It might be that the compiler is already telling you exactly what you need to do to fix your problem.
There may be reasons for the failure that aren't problems in OpenSSL itself, for example if the compiler reports missing standard or third party headers.
If the build succeeded previously, but fails after a source or configuration change, it might be helpful to clean the build tree before attempting another build. Use this command:
$ make clean # Unix
$ mms clean ! (or mmk) OpenVMS
$ nmake clean # Windows
Assembler error messages can sometimes be sidestepped by using the no-asm
configuration option. See also notes.
Compiling parts of OpenSSL with gcc and others with the system compiler will result in unresolved symbols on some systems.
If you are still having problems, try to search the openssl-users mailing list or the GitHub Issues for existing solutions. If you think you encountered an OpenSSL bug, please raise an issue to file a bug report. Please take the time to review the existing issues first; maybe the bug was already reported or has already been fixed.
If some tests fail, look at the output. There may be reasons for the failure that isn't a problem in OpenSSL itself (like an OS malfunction or a Perl issue).
You may want increased verbosity, that can be accomplished as described in section Test Failures of test/README.md.
You may also want to selectively specify which test(s) to perform. This can be
done using the make
variable TESTS
as described in section Running
Selected Tests of test/README.md.
If you find a problem with OpenSSL itself, try removing any
compiler optimization flags from the CFLAGS
line in the Makefile and
run make clean; make
or corresponding.
To report a bug please open an issue on GitHub, at https://github.com/openssl/openssl/issues.
For some systems, the OpenSSL Configure
script knows what compiler options
are needed to generate a library that is suitable for multi-threaded
applications. On these systems, support for multi-threading is enabled
by default; use the no-threads
option to disable (this should never be
necessary).
On other systems, to enable support for multi-threading, you will have
to specify at least two options: threads
, and a system-dependent option.
(The latter is -D_REENTRANT
on various systems.) The default in this
case, obviously, is not to include support for multi-threading (but
you can still use no-threads
to suppress an annoying warning message
from the Configure
script.)
OpenSSL provides built-in support for two threading models: pthreads (found on
most UNIX/Linux systems), and Windows threads. No other threading models are
supported. If your platform does not provide pthreads or Windows threads then
you should use Configure
with the no-threads
option.
For pthreads, all locks are non-recursive. In addition, in a debug build,
the mutex attribute PTHREAD_MUTEX_ERRORCHECK
is used. If this is not
available on your platform, you might have to add
-DOPENSSL_NO_MUTEX_ERRORCHECK
to your Configure
invocation.
(On Linux PTHREAD_MUTEX_ERRORCHECK
is an enum value, so a built-in
ifdef test cannot be used.)
For most systems the OpenSSL Configure
script knows what is needed to
build shared libraries for libcrypto and libssl. On these systems
the shared libraries will be created by default. This can be suppressed and
only static libraries created by using the no-shared
option. On systems
where OpenSSL does not know how to build shared libraries the no-shared
option will be forced and only static libraries will be created.
Shared libraries are named a little differently on different platforms.
One way or another, they all have the major OpenSSL version number as
part of the file name, i.e. for OpenSSL 1.1.x, 1.1
is somehow part of
the name.
On most POSIX platforms, shared libraries are named libcrypto.so.1.1
and libssl.so.1.1
.
on Cygwin, shared libraries are named cygcrypto-1.1.dll
and cygssl-1.1.dll
with import libraries libcrypto.dll.a
and libssl.dll.a
.
On Windows build with MSVC or using MingW, shared libraries are named
libcrypto-1_1.dll
and libssl-1_1.dll
for 32-bit Windows,
libcrypto-1_1-x64.dll
and libssl-1_1-x64.dll
for 64-bit x86_64 Windows,
and libcrypto-1_1-ia64.dll
and libssl-1_1-ia64.dll
for IA64 Windows.
With MSVC, the import libraries are named libcrypto.lib
and libssl.lib
,
while with MingW, they are named libcrypto.dll.a
and libssl.dll.a
.
On VMS, shareable images (VMS speak for shared libraries) are named
ossl$libcrypto0101_shr.exe
and ossl$libssl0101_shr.exe
. However, when
OpenSSL is specifically built for 32-bit pointers, the shareable images
are named ossl$libcrypto0101_shr32.exe
and ossl$libssl0101_shr32.exe
instead, and when built for 64-bit pointers, they are named
ossl$libcrypto0101_shr64.exe
and ossl$libssl0101_shr64.exe
.
Availability of cryptographically secure random numbers is required for secret key generation. OpenSSL provides several options to seed the internal CSPRNG. If not properly seeded, the internal CSPRNG will refuse to deliver random bytes and a "PRNG not seeded error" will occur.
The seeding method can be configured using the --with-rand-seed
option,
which can be used to specify a comma separated list of seed methods.
However, in most cases OpenSSL will choose a suitable default method,
so it is not necessary to explicitly provide this option. Note also
that not all methods are available on all platforms. The FIPS provider will
silently ignore seed sources that were not validated.
I) On operating systems which provide a suitable randomness source (in
form of a system call or system device), OpenSSL will use the optimal
available method to seed the CSPRNG from the operating system's
randomness sources. This corresponds to the option --with-rand-seed=os
.
II) On systems without such a suitable randomness source, automatic seeding
and reseeding is disabled (--with-rand-seed=none
) and it may be necessary
to install additional support software to obtain a random seed and reseed
the CSPRNG manually. Please check out the manual pages for RAND_add()
,
RAND_bytes()
, RAND_egd()
, and the FAQ for more information.
Compilation of some code paths in assembler modules might depend on whether the current assembler version supports certain ISA extensions or not. Code paths that use the AES-NI, PCLMULQDQ, SSSE3, and SHA extensions are always assembled. Apart from that, the minimum requirements for the assembler versions are shown in the table below:
ISA extension | GNU as | nasm | llvm |
---|---|---|---|
AVX | 2.19 | 2.09 | 3.0 |
AVX2 | 2.22 | 2.10 | 3.1 |
ADCX/ADOX | 2.23 | 2.10 | 3.3 |
AVX512 | 2.25 | 2.11.8 | 3.6 (*) |
AVX512IFMA | 2.26 | 2.11.8 | 6.0 (*) |
VAES | 2.30 | 2.13.3 | 6.0 (*) |
(*) Even though AVX512 support was implemented in llvm 3.6, prior to version 7.0
an explicit -march flag was apparently required to compile assembly modules. But
then the compiler generates processor-specific code, which in turn contradicts
the idea of performing dispatch at run-time, which is facilitated by the special
variable OPENSSL_ia32cap
. For versions older than 7.0, it is possible to work
around the problem by forcing the build procedure to use the following script:
#!/bin/sh
exec clang -no-integrated-as "$@"
instead of the real clang. In which case it doesn't matter what clang version is used, as it is the version of the GNU assembler that will be checked.