Reseeding is handled very differently by the classic RAND_METHOD API
and the new RAND_DRBG api. These differences led to some problems when
the new RAND_DRBG was made the default OpenSSL RNG. In particular,
RAND_add() did not work as expected anymore. These issues are discussed
on the thread '[openssl-dev] Plea for a new public OpenSSL RNG API'
and in Pull Request #4328. This commit fixes the mentioned issues,
introducing the following changes:
- Replace the fixed size RAND_BYTES_BUFFER by a new RAND_POOL API which
facilitates collecting entropy by the get_entropy() callback.
- Don't use RAND_poll()/RAND_add() for collecting entropy from the
get_entropy() callback anymore. Instead, replace RAND_poll() by
RAND_POOL_acquire_entropy().
- Add a new function rand_drbg_restart() which tries to get the DRBG
in an instantiated state by all means, regardless of the current
state (uninstantiated, error, ...) the DRBG is in. If the caller
provides entropy or additional input, it will be used for reseeding.
- Restore the original documented behaviour of RAND_add() and RAND_poll()
(namely to reseed the DRBG immediately) by a new implementation based
on rand_drbg_restart().
- Add automatic error recovery from temporary failures of the entropy
source to RAND_DRBG_generate() using the rand_drbg_restart() function.
Reviewed-by: Paul Dale <paul.dale@oracle.com>
Reviewed-by: Kurt Roeckx <kurt@roeckx.be>
Reviewed-by: Rich Salz <rsalz@openssl.org>
Reviewed-by: Ben Kaduk <kaduk@mit.edu>
(Merged from https://github.com/openssl/openssl/pull/4328)
How to add recipes
==================
For any test that you want to perform, you write a script located in
test/recipes/, named {nn}-test_{name}.t, where {nn} is a two digit number and
{name} is a unique name of your choice.
Please note that if a test involves a new testing executable, you will need to
do some additions in test/Makefile. More on this later.
Naming conventions
=================
A test executable is named test/{name}test.c
A test recipe is named test/recipes/{nn}-test_{name}.t, where {nn} is a two
digit number and {name} is a unique name of your choice.
The number {nn} is (somewhat loosely) grouped as follows:
00-04 sanity, internal and essential API tests
05-09 individual symmetric cipher algorithms
10-14 math (bignum)
15-19 individual asymmetric cipher algorithms
20-24 openssl commands (some otherwise not tested)
25-29 certificate forms, generation and verification
30-35 engine and evp
60-79 APIs
70 PACKET layer
80-89 "larger" protocols (CA, CMS, OCSP, SSL, TSA)
90-98 misc
99 most time consuming tests [such as test_fuzz]
A recipe that just runs a test executable
=========================================
A script that just runs a program looks like this:
#! /usr/bin/perl
use OpenSSL::Test::Simple;
simple_test("test_{name}", "{name}test", "{name}");
{name} is the unique name you have chosen for your test.
The second argument to `simple_test' is the test executable, and `simple_test'
expects it to be located in test/
For documentation on OpenSSL::Test::Simple, do
`perldoc util/perl/OpenSSL/Test/Simple.pm'.
A recipe that runs a more complex test
======================================
For more complex tests, you will need to read up on Test::More and
OpenSSL::Test. Test::More is normally preinstalled, do `man Test::More' for
documentation. For OpenSSL::Test, do `perldoc util/perl/OpenSSL/Test.pm'.
A script to start from could be this:
#! /usr/bin/perl
use strict;
use warnings;
use OpenSSL::Test;
setup("test_{name}");
plan tests => 2; # The number of tests being performed
ok(test1, "test1");
ok(test2, "test1");
sub test1
{
# test feature 1
}
sub test2
{
# test feature 2
}
Changes to test/build.info
==========================
Whenever a new test involves a new test executable you need to do the
following (at all times, replace {NAME} and {name} with the name of your
test):
* add {name} to the list of programs under PROGRAMS_NO_INST
* create a three line description of how to build the test, you will have
to modify the include paths and source files if you don't want to use the
basic test framework:
SOURCE[{name}]={name}.c
INCLUDE[{name}]=.. ../include
DEPEND[{name}]=../libcrypto libtestutil.a
Generic form of C test executables
==================================
#include "testutil.h"
static int my_test(void)
{
int testresult = 0; /* Assume the test will fail */
int observed;
observed = function(); /* Call the code under test */
if (!TEST_int_equal(observed, 2)) /* Check the result is correct */
goto end; /* Exit on failure - optional */
testresult = 1; /* Mark the test case a success */
end:
cleanup(); /* Any cleanup you require */
return testresult;
}
int setup_tests(void)
{
ADD_TEST(my_test); /* Add each test separately */
return 1; /* Indicate success */
}
You should use the TEST_xxx macros provided by testutil.h to test all failure
conditions. These macros produce an error message in a standard format if the
condition is not met (and nothing if the condition is met). Additional
information can be presented with the TEST_info macro that takes a printf
format string and arguments. TEST_error is useful for complicated conditions,
it also takes a printf format string and argument. In all cases the TEST_xxx
macros are guaranteed to evaluate their arguments exactly once. This means
that expressions with side effects are allowed as parameters. Thus,
if (!TEST_ptr(ptr = OPENSSL_malloc(..)))
works fine and can be used in place of:
ptr = OPENSSL_malloc(..);
if (!TEST_ptr(ptr))
The former produces a more meaningful message on failure than the latter.
c16de9d832