INSTALLATION ON THE UNIX PLATFORM --------------------------------- [For instructions for compiling OpenSSL on Windows systems, see INSTALL.W32]. To install OpenSSL, you will need: * Perl 5 * ANSI C compiler * a supported Unix operating system Quick Start ----------- If you want to just get on with it, do: $ ./config [if this fails, go to step 1b below] $ make $ make rehash $ make test $ make install This will build and install OpenSSL in the default location, which is (for historical reasons) /usr/local/ssl. If you want to install it anywhere else, do this after running `./config': $ perl util/ssldir.pl /new/install/path There are several options to ./config to customize the build: rsaref Build with RSADSI's RSAREF toolkit. no-asm Build with no assembler code. 386 Use the 80386 instruction set only (the default x86 code is more efficient, but requires at least a 486). If anything goes wrong, follow the detailed instructions below. If your operating system is not (yet) supported by OpenSSL, see the section on porting to a new system. Installation in Detail ---------------------- 1a. Configure OpenSSL for your operation system automatically: $ ./config This guesses at your operating system (and compiler, if necessary) and configures OpenSSL based on this guess. Check the first line of output to see if it guessed correctly. If it did not get it correct or you want to use a different compiler then go to step 1b. Otherwise go to step 2. 1b. Configure OpenSSL for your operating system manually OpenSSL knows about a range of different operating system, hardware and compiler combinations. To see the ones it knows about, run $ ./Configure 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 If your system is not available, you will have to edit the Configure program and add the correct configuration for your system. Configure creates the Makefile.ssl from Makefile.org and defines various macros in crypto/opensslconf.h (generated from crypto/opensslconf.h.in). 2. Set the install directory If the install directory will be the default of /usr/local/ssl, skip to the next stage. Otherwise, run $ perl util/ssldir.pl /new/install/path This configures the installation location into the "install" target of the top-level Makefile, and also updates some defines in an include file so that the default certificate directory is under the proper installation directory. It also updates a few utility files used in the build process. 3. Build OpenSSL by running: $ make This will build the OpenSSL libraries (libcrypto.a and libssl.a) and the OpenSSL binary ("openssl"). The libraries will be built in the top-level directory, and the binary will be in the "apps" directory. 4. After a successful build, the libraries should be tested. Run: $ make rehash $ make test (The first line makes the test certificates in the "certs" directory accessable via an hash name, which is required for some of the tests). 5. If everything tests ok, install OpenSSL with $ make install This will create the installation directory (if it does not exist) and then create the following subdirectories: bin Contains the openssl binary and a few other utility programs. include Contains the header files needed if you want to compile programs with libcrypto or libssl. lib Contains the library files themselves and the OpenSSL configuration file "openssl.cnf". certs Initially empty, this is the default location for certificate files. private Initially empty, this is the default location for private key files. NOTE: The header files used to reside directly in the include directory, but have now been moved to include/openssl so that OpenSSL can co-exist with other libraries which use some of the same filenames. This means that applications that use OpenSSL should now use C preprocessor directives of the form #include instead of "#include ", which was used with library versions up to OpenSSL 0.9.2b. If you install a new version of OpenSSL over an old library version, you should delete the old header files in the include directory. Compatibility issues: * COMPILING existing applications To compile an application that uses old filenames -- e.g. "#include " --, it will usually be enough to find the CFLAGS definition in the application's Makefile and add a C option such as -I/usr/local/ssl/include/openssl to it. But don't delete the existing -I option that points to the ..../include directory! Otherwise, OpenSSL header files could not #include each other. * WRITING applications To write an application that is able to handle both the new and the old directory layout, so that it can still be compiled with library versions up to OpenSSL 0.9.2b without bothering the user, you can proceed as follows: - Always use the new filename of OpenSSL header files, e.g. #include . - Create a directory "incl" that contains only a symbolic link named "openssl", which points to the "include" directory of OpenSSL. For example, your application's Makefile might contain the following rule, if OPENSSLDIR is a pathname (absolute or relative) of the directory where OpenSSL resides: incl/openssl: -mkdir incl cd $(OPENSSLDIR) # Check whether the directory really exists -ln -s `cd $(OPENSSLDIR); pwd`/include incl/openssl You will have to add "incl/openssl" to the dependencies of those C files that include some OpenSSL header file. - Add "-Iincl" to your CFLAGS. With these additions, the OpenSSL header files will be available under both name variants if an old library version is used: Your application can reach them under names like , while the header files still are able to #include each other with names of the form . -------------------------------------------------------------------------------- The orignal Unix build instructions from SSLeay follow. Note: some of this may be out of date and no longer applicable -------------------------------------------------------------------------------- # When bringing the SSLeay distribution back from the evil intel world # of Windows NT, do the following to make it nice again under unix :-) # You don't normally need to run this. sh util/fixNT.sh # This only works for NT now - eay - 21-Jun-1996 # If you have perl, and it is not in /usr/local/bin, you can run perl util/perlpath.pl /new/path # and this will fix the paths in all the scripts. DO NOT put # /new/path/perl, just /new/path. The build # environment always run scripts as 'perl perlscript.pl' but some of the # 'applications' are easier to usr with the path fixed. # Edit crypto/cryptlib.h, tools/c_rehash, and Makefile.ssl # to set the install locations if you don't like # the default location of /usr/local/ssl # Do this by running perl util/ssldir.pl /new/ssl/home # if you have perl, or by hand if not. # If things have been stuffed up with the sym links, run make -f Makefile.ssl links # This will re-populate lib/include with symlinks and for each # directory, link Makefile to Makefile.ssl # Setup the machine dependent stuff for the top level makefile # and some select .h files # If you don't have perl, this will bomb, in which case just edit the # top level Makefile.ssl ./Configure 'system type' # The 'Configure' command contains default configuration parameters # for lots of machines. Configure edits 5 lines in the top level Makefile # It modifies the following values in the following files Makefile.ssl CC CFLAG EX_LIBS BN_MULW crypto/des/des.h DES_LONG crypto/des/des_locl.h DES_PTR crypto/md2/md2.h MD2_INT crypto/rc4/rc4.h RC4_INT crypto/rc4/rc4_enc.c RC4_INDEX crypto/rc2/rc2.h RC2_INT crypto/bf/bf_locl.h BF_INT crypto/idea/idea.h IDEA_INT crypto/bn/bn.h BN_LLONG (and defines one of SIXTY_FOUR_BIT, SIXTY_FOUR_BIT_LONG, THIRTY_TWO_BIT, SIXTEEN_BIT or EIGHT_BIT) Please remember that all these files are actually copies of the file with a .org extention. So if you change crypto/des/des.h, the next time you run Configure, it will be runover by a 'configured' version of crypto/des/des.org. So to make the changer the default, change the .org files. The reason these files have to be edited is because most of these modifications change the size of fundamental data types. While in theory this stuff is optional, it often makes a big difference in performance and when using assember, it is importaint for the 'Bignum bits' match those required by the assember code. A warning for people using gcc with sparc cpu's. Gcc needs the -mv8 flag to use the hardware multiply instruction which was not present in earlier versions of the sparc CPU. I define it by default. If you have an old sparc, and it crashes, try rebuilding with this flag removed. I am leaving this flag on by default because it makes things run 4 times faster :-) # clean out all the old stuff make clean # Do a make depend only if you have the makedepend command installed # This is not needed but it does make things nice when developing. make depend # make should build everything make # fix up the demo certificate hash directory if it has been stuffed up. make rehash # test everything make test # install the lot make install # It is worth noting that all the applications are built into the one # program, ssleay, which is then has links from the other programs # names to it. # The applicatons can be built by themselves, just don't define the # 'MONOLITH' flag. So to build the 'enc' program stand alone, gcc -O2 -Iinclude apps/enc.c apps/apps.c libcrypto.a # Other useful make options are make makefile.one # which generate a 'makefile.one' file which will build the complete # SSLeay distribution with temp. files in './tmp' and 'installable' files # in './out' # Have a look at running perl util/mk1mf.pl help # this can be used to generate a single makefile and is about the only # way to generate makefiles for windows. # There is actually a final way of building SSLeay. gcc -O2 -c -Icrypto -Iinclude crypto/crypto.c gcc -O2 -c -Issl -Iinclude ssl/ssl.c # and you now have the 2 libraries as single object files :-). # If you want to use the assember code for your particular platform # (DEC alpha/x86 are the main ones, the other assember is just the # output from gcc) you will need to link the assember with the above generated # object file and also do the above compile as gcc -O2 -DBN_ASM -c -Icrypto -Iinclude crypto/crypto.c This last option is probably the best way to go when porting to another platform or building shared libraries. It is not good for development so I don't normally use it. To build shared libararies under unix, have a look in shlib, basically you are on your own, but it is quite easy and all you have to do is compile 2 (or 3) files. For mult-threading, have a read of doc/threads.doc. Again it is quite easy and normally only requires some extra callbacks to be defined by the application. The examples for solaris and windows NT/95 are in the mt directory. have fun eric 25-Jun-1997 IRIX 5.x will build as a 32 bit system with mips1 assember. IRIX 6.x will build as a 64 bit system with mips3 assember. It conforms to n32 standards. In theory you can compile the 64 bit assember under IRIX 5.x but you will have to have the correct system software installed.