// -*- mode:C++; tab-width:8; c-basic-offset:2; indent-tabs-mode:t -*- // vim: ts=8 sw=2 smarttab /* * Ceph - scalable distributed file system * * Copyright (C) 2017 SUSE LINUX GmbH * * This is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License version 2.1, as published by the Free Software * Foundation. See file COPYING. * */ #include #include "include/random.h" #include "gtest/gtest.h" // Helper to see if calls compile with various types: template T type_check_ok(const T min, const T max) { return ceph::util::generate_random_number(min, max); } /* Help wrangle "unused variable" warnings: */ template void swallow_values(const X x) { static_cast(x); } template void swallow_values(const X x, const XS... xs) { swallow_values(x), swallow_values(xs...); } // Mini-examples showing canonical usage: TEST(util, test_random_canonical) { // Seed random number generation: ceph::util::randomize_rng(); // Get a random int between 0 and max int: auto a = ceph::util::generate_random_number(); // Get a random int between 0 and 20: auto b = ceph::util::generate_random_number(20); // Get a random int between 1 and 20: auto c = ceph::util::generate_random_number(1, 20); // Get a random float between 0.0 and 20.0: auto d = ceph::util::generate_random_number(20.0); // Get a random float between 0.001 and 0.991: auto e = ceph::util::generate_random_number(0.001, 0.991); // Make a function object RNG suitable for putting on its own thread: auto gen_fn = ceph::util::random_number_generator(); auto z = gen_fn(); gen_fn.seed(42); // re-seed // Placate the compiler: swallow_values(a, b, c, d, e, z); } TEST(util, test_random) { /* The intent of this test is not to formally test random number generation, but rather to casually check that "it works" and catch regressions: */ // The default overload should compile: ceph::util::randomize_rng(); { int a = ceph::util::generate_random_number(); int b = ceph::util::generate_random_number(); /* Technically, this can still collide and cause a false negative, but let's be optimistic: */ if (std::numeric_limits::max() > 32767) { ASSERT_NE(a, b); } } // Check that the nullary version accepts different numeric types: { long def = ceph::util::generate_random_number(); long l = ceph::util::generate_random_number(); int64_t i = ceph::util::generate_random_number(); double d = ceph::util::generate_random_number(); swallow_values(def, l, i, d); } // (optimistically) Check that the nullary and unary versions never return < 0: { for(long i = 0; 1000000 != i; i++) { ASSERT_LE(0, ceph::util::generate_random_number()); ASSERT_LE(0, ceph::util::generate_random_number(1)); ASSERT_LE(0, ceph::util::generate_random_number(1.0)); } } { auto a = ceph::util::generate_random_number(1, std::numeric_limits::max()); auto b = ceph::util::generate_random_number(1, std::numeric_limits::max()); if (std::numeric_limits::max() > 32767) { ASSERT_GT(a, 0); ASSERT_GT(b, 0); ASSERT_NE(a, b); } } for (auto n = 100000; n; --n) { int a = ceph::util::generate_random_number(0, 6); ASSERT_GT(a, -1); ASSERT_LT(a, 7); } // Check bounding on zero (checking appropriate value for zero compiles and works): for (auto n = 10; n; --n) { ASSERT_EQ(0, ceph::util::generate_random_number(0, 0)); ASSERT_EQ(0, ceph::util::generate_random_number(0.0, 0.0)); } // Multiple types (integral): { int min = 0, max = 1; type_check_ok(min, max); } { long min = 0, max = 1l; type_check_ok(min, max); } // Multiple types (floating point): { double min = 0.0, max = 1.0; type_check_ok(min, max); } { float min = 0.0, max = 1.0; type_check_ok(min, max); } // min > max should not explode: { float min = 1.0, max = 0.0; type_check_ok(min, max); } // When combining types, everything should convert to the largest type: { // Check with integral types: { int x = 0; long long y = 1; auto z = ceph::util::generate_random_number(x, y); bool result = std::is_same_v; ASSERT_TRUE(result); } // Check with floating-point types: { float x = 0.0; long double y = 1.0; auto z = ceph::util::generate_random_number(x, y); bool result = std::is_same_v; ASSERT_TRUE(result); } // It would be nice to have a test to check that mixing integral and floating point // numbers should not compile, however we currently have no good way I know of // to do such negative tests. } } TEST(util, test_random_class_interface) { ceph::util::random_number_generator rng_i; ceph::util::random_number_generator rng_f; // Other ctors: { ceph::util::random_number_generator rng(1234); // seed } { int a = rng_i(); int b = rng_i(); // Technically can fail, but should "almost never" happen: ASSERT_NE(a, b); } { int a = rng_i(10); ASSERT_LE(a, 10); ASSERT_GE(a, 0); } { float a = rng_f(10.0); ASSERT_LE(a, 10.0); ASSERT_GE(a, 0.0); } { int a = rng_i(10, 20); ASSERT_LE(a, 20); ASSERT_GE(a, 10); } { float a = rng_f(10.0, 20.0); ASSERT_LE(a, 20.0); ASSERT_GE(a, 10.0); } }