/* Copyright 2018 The Chromium OS Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. * * Test util.[ch] module code using gtest. */ #include #include #include #include #include #include #include "bpf.h" #include "util.h" namespace { std::string dump_env(const char *const *env) { std::string result; for (; *env; ++env) { result += *env; result += "\n"; } return result; } } // namespace // Sanity check for the strip func. TEST(strip, basic) { char str[] = " foo\t"; ASSERT_EQ("foo", std::string(strip(str))); } // Make sure we don't crash with various "null"-like inputs. TEST(tokenize, null_stringp) { ASSERT_EQ(nullptr, tokenize(nullptr, nullptr)); ASSERT_EQ(nullptr, tokenize(nullptr, "")); ASSERT_EQ(nullptr, tokenize(nullptr, ",")); char *p = nullptr; ASSERT_EQ(nullptr, tokenize(&p, nullptr)); } // Make sure we don't crash with various "null"-like inputs. TEST(tokenize, null_delim) { char str[] = "a,b,c"; char *p = str; ASSERT_EQ(str, tokenize(&p, nullptr)); ASSERT_EQ(nullptr, p); ASSERT_EQ(str, std::string("a,b,c")); p = str; ASSERT_EQ(str, tokenize(&p, "")); ASSERT_EQ(nullptr, p); ASSERT_EQ(str, std::string("a,b,c")); } // Sanity check for the tokenize func. TEST(tokenize, basic) { char str[] = "a,b,c"; char *p = str; ASSERT_EQ("a", std::string(tokenize(&p, ","))); ASSERT_EQ("b", std::string(tokenize(&p, ","))); ASSERT_EQ("c", std::string(tokenize(&p, ","))); ASSERT_EQ(nullptr, p); ASSERT_EQ(nullptr, tokenize(&p, ",")); } // Check edge case with an empty string. TEST(tokenize, empty_string) { char str[] = ""; char *p = str; ASSERT_EQ("", std::string(tokenize(&p, ","))); ASSERT_EQ(nullptr, p); ASSERT_EQ(nullptr, tokenize(&p, ",")); } // Check behavior with empty tokens at the start/middle/end. TEST(tokenize, empty_tokens) { char str[] = ",,a,b,,,c,,"; char *p = str; ASSERT_EQ("", std::string(tokenize(&p, ","))); ASSERT_EQ("", std::string(tokenize(&p, ","))); ASSERT_EQ("a", std::string(tokenize(&p, ","))); ASSERT_EQ("b", std::string(tokenize(&p, ","))); ASSERT_EQ("", std::string(tokenize(&p, ","))); ASSERT_EQ("", std::string(tokenize(&p, ","))); ASSERT_EQ("c", std::string(tokenize(&p, ","))); ASSERT_EQ("", std::string(tokenize(&p, ","))); ASSERT_EQ("", std::string(tokenize(&p, ","))); ASSERT_EQ(nullptr, p); ASSERT_EQ(nullptr, tokenize(&p, ",")); } // Check environment manipulation functions. TEST(environment, copy_and_modify) { minijail_free_env(nullptr); char **env = minijail_copy_env(nullptr); EXPECT_EQ("", dump_env(env)); minijail_free_env(env); const char *const kConstEnv[] = { "val1=1", "val2=2", "dup=1", "dup=2", "empty=", nullptr, }; // libc unfortunately uses char* const[] as the type for the environment, and // we match that. It's actually missing a const-ness of the chars making up // the environment strings, but we need that to initialize the |kEnv| // constant. Hence, do a cast here to force things into alignment... char* const* kEnv = const_cast(kConstEnv); env = minijail_copy_env(kEnv); EXPECT_EQ("val1=1\nval2=2\ndup=1\ndup=2\nempty=\n", dump_env(env)); minijail_free_env(env); env = minijail_copy_env(kEnv); EXPECT_EQ("val1=1\nval2=2\ndup=1\ndup=2\nempty=\n", dump_env(env)); EXPECT_EQ(EINVAL, minijail_setenv(nullptr, "val1", "3", 1)); char **env_ret = nullptr; EXPECT_EQ(EINVAL, minijail_setenv(&env_ret, "val1", "3", 1)); env_ret = env; EXPECT_EQ(EINVAL, minijail_setenv(&env_ret, nullptr, "3", 1)); EXPECT_EQ(env, env_ret); EXPECT_EQ(EINVAL, minijail_setenv(&env_ret, "", "3", 1)); EXPECT_EQ(env, env_ret); EXPECT_EQ(EINVAL, minijail_setenv(&env_ret, "", nullptr, 1)); EXPECT_EQ(env, env_ret); EXPECT_EQ(0, minijail_setenv(&env, "val1", "3", 0)); EXPECT_EQ("val1=1\nval2=2\ndup=1\ndup=2\nempty=\n", dump_env(env)); EXPECT_EQ(0, minijail_setenv(&env, "val1", "3", 1)); EXPECT_EQ("val1=3\nval2=2\ndup=1\ndup=2\nempty=\n", dump_env(env)); EXPECT_EQ(0, minijail_setenv(&env, "val2", "4", 1)); EXPECT_EQ("val1=3\nval2=4\ndup=1\ndup=2\nempty=\n", dump_env(env)); EXPECT_EQ(0, minijail_setenv(&env, "dup", "5", 1)); EXPECT_EQ("val1=3\nval2=4\ndup=5\ndup=2\nempty=\n", dump_env(env)); EXPECT_EQ(0, minijail_setenv(&env, "empty", "6", 1)); EXPECT_EQ("val1=3\nval2=4\ndup=5\ndup=2\nempty=6\n", dump_env(env)); EXPECT_EQ(0, minijail_setenv(&env, "empty", "", 1)); EXPECT_EQ("val1=3\nval2=4\ndup=5\ndup=2\nempty=\n", dump_env(env)); EXPECT_EQ(0, minijail_setenv(&env, "new1", "7", 0)); EXPECT_EQ("val1=3\nval2=4\ndup=5\ndup=2\nempty=\nnew1=7\n", dump_env(env)); EXPECT_EQ(0, minijail_setenv(&env, "new2", "8", 1)); EXPECT_EQ("val1=3\nval2=4\ndup=5\ndup=2\nempty=\nnew1=7\nnew2=8\n", dump_env(env)); minijail_free_env(env); } TEST(parse_single_constant, formats) { char *end; long int c = 0; std::string constant; // Check base 10 works. constant = "1234"; c = parse_constant(const_cast(constant.data()), &end); EXPECT_EQ(1234, c); // Check base 16 works. constant = "0x1234"; c = parse_constant(const_cast(constant.data()), &end); EXPECT_EQ(0x1234, c); // Check base 8 works. constant = "01234"; c = parse_constant(const_cast(constant.data()), &end); EXPECT_EQ(01234, c); } TEST(parse_constant, unsigned) { char *end; long int c = 0; std::string constant; #if defined(BITS32) constant = "0x80000000"; c = parse_constant(const_cast(constant.data()), &end); EXPECT_EQ(0x80000000U, static_cast(c)); #elif defined(BITS64) constant = "0x8000000000000000"; c = parse_constant(const_cast(constant.data()), &end); EXPECT_EQ(0x8000000000000000UL, static_cast(c)); #else # error "unknown bits!" #endif } TEST(parse_constant, unsigned_toobig) { char *end; long int c = 0; std::string constant; #if defined(BITS32) constant = "0x100000000"; // Too big for 32-bit unsigned long int. c = parse_constant(const_cast(constant.data()), &end); // Error case should return 0. EXPECT_EQ(0, c); #elif defined(BITS64) constant = "0x10000000000000000"; c = parse_constant(const_cast(constant.data()), &end); // Error case should return 0. EXPECT_EQ(0, c); #else # error "unknown bits!" #endif } TEST(parse_constant, signed) { char *end; long int c = 0; std::string constant = "-1"; c = parse_constant(const_cast(constant.data()), &end); EXPECT_EQ(-1, c); } TEST(parse_constant, signed_toonegative) { char *end; long int c = 0; std::string constant; #if defined(BITS32) constant = "-0x80000001"; c = parse_constant(const_cast(constant.data()), &end); // Error case should return 0. EXPECT_EQ(0, c); #elif defined(BITS64) constant = "-0x8000000000000001"; c = parse_constant(const_cast(constant.data()), &end); // Error case should return 0. EXPECT_EQ(0, c); #else # error "unknown bits!" #endif } TEST(parse_constant, complements) { char* end; long int c = 0; std::string constant; #if defined(BITS32) constant = "~0x005AF0FF|~0xFFA50FFF"; c = parse_constant(const_cast(constant.data()), &end); EXPECT_EQ(c, 0xFFFFFF00); constant = "0x0F|~(0x005AF000|0x00A50FFF)|0xF0"; c = parse_constant(const_cast(constant.data()), &end); EXPECT_EQ(c, 0xFF0000FF); #elif defined(BITS64) constant = "~0x00005A5AF0F0FFFF|~0xFFFFA5A50F0FFFFF"; c = parse_constant(const_cast(constant.data()), &end); EXPECT_EQ(c, 0xFFFFFFFFFFFF0000UL); constant = "0x00FF|~(0x00005A5AF0F00000|0x0000A5A50F0FFFFF)|0xFF00"; c = parse_constant(const_cast(constant.data()), &end); EXPECT_EQ(c, 0xFFFF00000000FFFFUL); #else # error "unknown bits!" #endif } TEST(parse_constant, parenthesized_expresions) { char* end; const std::vector bad_expressions = { "(1", "1)", "(1)1", "|(1)", "(1)|", "()", "(", "((", "(()", "(()1", "1(0)", }; for (const auto* expression : bad_expressions) { std::string mutable_expression = expression; long int c = parse_constant(const_cast(mutable_expression.data()), &end); EXPECT_EQ(reinterpret_cast(end), reinterpret_cast(mutable_expression.data())); // Error case should return 0. EXPECT_EQ(c, 0) << "For expression: \"" << expression << "\""; } const std::vector good_expressions = { "(3)", "(1)|2", "1|(2)", "(1)|(2)", "((3))", "0|(1|2)", "(0|1|2)", }; for (const auto* expression : good_expressions) { std::string mutable_expression = expression; long int c = parse_constant(const_cast(mutable_expression.data()), &end); EXPECT_EQ(c, 3) << "For expression: \"" << expression << "\""; } } TEST(parse_size, complete) { size_t size; ASSERT_EQ(0, parse_size(&size, "42")); ASSERT_EQ(42U, size); ASSERT_EQ(0, parse_size(&size, "16K")); ASSERT_EQ(16384U, size); ASSERT_EQ(0, parse_size(&size, "1M")); ASSERT_EQ(1024U * 1024, size); uint64_t gigabyte = 1024ULL * 1024 * 1024; ASSERT_EQ(0, parse_size(&size, "3G")); ASSERT_EQ(3U, size / gigabyte); ASSERT_EQ(0U, size % gigabyte); ASSERT_EQ(0, parse_size(&size, "4294967294")); ASSERT_EQ(3U, size / gigabyte); ASSERT_EQ(gigabyte - 2, size % gigabyte); #if __WORDSIZE == 64 uint64_t exabyte = gigabyte * 1024 * 1024 * 1024; ASSERT_EQ(0, parse_size(&size, "9E")); ASSERT_EQ(9U, size / exabyte); ASSERT_EQ(0U, size % exabyte); ASSERT_EQ(0, parse_size(&size, "15E")); ASSERT_EQ(15U, size / exabyte); ASSERT_EQ(0U, size % exabyte); ASSERT_EQ(0, parse_size(&size, "18446744073709551614")); ASSERT_EQ(15U, size / exabyte); ASSERT_EQ(exabyte - 2, size % exabyte); ASSERT_EQ(-ERANGE, parse_size(&size, "16E")); ASSERT_EQ(-ERANGE, parse_size(&size, "19E")); ASSERT_EQ(-EINVAL, parse_size(&size, "7GTPE")); #elif __WORDSIZE == 32 ASSERT_EQ(-ERANGE, parse_size(&size, "5G")); ASSERT_EQ(-ERANGE, parse_size(&size, "9G")); ASSERT_EQ(-ERANGE, parse_size(&size, "9E")); ASSERT_EQ(-ERANGE, parse_size(&size, "7GTPE")); #endif ASSERT_EQ(-EINVAL, parse_size(&size, "")); ASSERT_EQ(-EINVAL, parse_size(&size, "14u")); ASSERT_EQ(-EINVAL, parse_size(&size, "14.2G")); ASSERT_EQ(-EINVAL, parse_size(&size, "-1G")); ASSERT_EQ(-EINVAL, parse_size(&size, "; /bin/rm -- ")); }