/* * Copyright (c) 2020, Ben Wiederhake * * SPDX-License-Identifier: BSD-2-Clause */ #include #include #include #include #include #include #include struct Testcase { char const* dest; size_t dest_n; char const* src; size_t src_n; char const* dest_expected; size_t dest_expected_n; // == dest_n }; static ByteString show(ByteBuffer const& buf) { StringBuilder builder; for (size_t i = 0; i < buf.size(); ++i) { builder.appendff("{:02x}", buf[i]); } builder.append(' '); builder.append('('); for (size_t i = 0; i < buf.size(); ++i) { if (isprint(buf[i])) builder.append(buf[i]); else builder.append('_'); } builder.append(')'); return builder.to_byte_string(); } static bool test_single(Testcase const& testcase) { constexpr size_t SANDBOX_CANARY_SIZE = 8; // Preconditions: if (testcase.dest_n != testcase.dest_expected_n) { warnln("dest length {} != expected dest length {}? Check testcase! (Probably miscounted.)", testcase.dest_n, testcase.dest_expected_n); return false; } if (testcase.src_n != strlen(testcase.src)) { warnln("src length {} != actual src length {}? src can't contain NUL bytes!", testcase.src_n, strlen(testcase.src)); return false; } // Setup ByteBuffer actual = ByteBuffer::create_uninitialized(SANDBOX_CANARY_SIZE + testcase.dest_n + SANDBOX_CANARY_SIZE).release_value(); fill_with_random(actual); ByteBuffer expected = actual; VERIFY(actual.offset_pointer(0) != expected.offset_pointer(0)); actual.overwrite(SANDBOX_CANARY_SIZE, testcase.dest, testcase.dest_n); expected.overwrite(SANDBOX_CANARY_SIZE, testcase.dest_expected, testcase.dest_expected_n); // "unsigned char" != "char", so we have to convince the compiler to allow this. char* dst = reinterpret_cast(actual.offset_pointer(SANDBOX_CANARY_SIZE)); // The actual call: size_t actual_return = strlcpy(dst, testcase.src, testcase.dest_n); // Checking the results: bool return_ok = actual_return == testcase.src_n; bool canary_1_ok = MUST(actual.slice(0, SANDBOX_CANARY_SIZE)) == MUST(expected.slice(0, SANDBOX_CANARY_SIZE)); bool main_ok = MUST(actual.slice(SANDBOX_CANARY_SIZE, testcase.dest_n)) == MUST(expected.slice(SANDBOX_CANARY_SIZE, testcase.dest_n)); bool canary_2_ok = MUST(actual.slice(SANDBOX_CANARY_SIZE + testcase.dest_n, SANDBOX_CANARY_SIZE)) == MUST(expected.slice(SANDBOX_CANARY_SIZE + testcase.dest_n, SANDBOX_CANARY_SIZE)); bool buf_ok = actual == expected; // Evaluate gravity: if (buf_ok && (!canary_1_ok || !main_ok || !canary_2_ok)) { warnln("Internal error! ({} != {} | {} | {})", buf_ok, canary_1_ok, main_ok, canary_2_ok); buf_ok = false; } if (!canary_1_ok) { warnln("Canary 1 overwritten: Expected canary {}\n" " instead got {}", show(MUST(expected.slice(0, SANDBOX_CANARY_SIZE))), show(MUST(actual.slice(0, SANDBOX_CANARY_SIZE)))); } if (!main_ok) { warnln("Wrong output: Expected {}\n" " instead got {}", show(MUST(expected.slice(SANDBOX_CANARY_SIZE, testcase.dest_n))), show(MUST(actual.slice(SANDBOX_CANARY_SIZE, testcase.dest_n)))); } if (!canary_2_ok) { warnln("Canary 2 overwritten: Expected {}\n" " instead got {}", show(MUST(expected.slice(SANDBOX_CANARY_SIZE + testcase.dest_n, SANDBOX_CANARY_SIZE))), show(MUST(actual.slice(SANDBOX_CANARY_SIZE + testcase.dest_n, SANDBOX_CANARY_SIZE)))); } if (!return_ok) { warnln("Wrong return value: Expected {}, got {} instead!", testcase.src_n, actual_return); } return buf_ok && return_ok; } // Drop the NUL terminator added by the C++ compiler. #define LITERAL(x) x, (sizeof(x) - 1) TEST_CASE(golden_path) { EXPECT(test_single({ LITERAL("Hello World!\0\0\0"), LITERAL("Hello Friend!"), LITERAL("Hello Friend!\0\0") })); EXPECT(test_single({ LITERAL("Hello World!\0\0\0"), LITERAL("Hello Friend!"), LITERAL("Hello Friend!\0\0") })); EXPECT(test_single({ LITERAL("aaaaaaaaaa"), LITERAL("whf"), LITERAL("whf\0aaaaaa") })); } TEST_CASE(exact_fit) { EXPECT(test_single({ LITERAL("Hello World!\0\0"), LITERAL("Hello Friend!"), LITERAL("Hello Friend!\0") })); EXPECT(test_single({ LITERAL("AAAA"), LITERAL("aaa"), LITERAL("aaa\0") })); } TEST_CASE(off_by_one) { EXPECT(test_single({ LITERAL("AAAAAAAAAA"), LITERAL("BBBBB"), LITERAL("BBBBB\0AAAA") })); EXPECT(test_single({ LITERAL("AAAAAAAAAA"), LITERAL("BBBBBBBCC"), LITERAL("BBBBBBBCC\0") })); EXPECT(test_single({ LITERAL("AAAAAAAAAA"), LITERAL("BBBBBBBCCX"), LITERAL("BBBBBBBCC\0") })); EXPECT(test_single({ LITERAL("AAAAAAAAAA"), LITERAL("BBBBBBBCCXY"), LITERAL("BBBBBBBCC\0") })); } TEST_CASE(nearly_empty) { EXPECT(test_single({ LITERAL(""), LITERAL(""), LITERAL("") })); EXPECT(test_single({ LITERAL(""), LITERAL("Empty test"), LITERAL("") })); EXPECT(test_single({ LITERAL("x"), LITERAL(""), LITERAL("\0") })); EXPECT(test_single({ LITERAL("xx"), LITERAL(""), LITERAL("\0x") })); EXPECT(test_single({ LITERAL("x"), LITERAL("y"), LITERAL("\0") })); } static char* const POISON = (char*)1; TEST_CASE(to_nullptr) { EXPECT_EQ(0u, strlcpy(POISON, "", 0)); EXPECT_EQ(1u, strlcpy(POISON, "x", 0)); EXPECT(test_single({ LITERAL("Hello World!\0\0\0"), LITERAL("Hello Friend!"), LITERAL("Hello Friend!\0\0") })); EXPECT(test_single({ LITERAL("aaaaaaaaaa"), LITERAL("whf"), LITERAL("whf\0aaaaaa") })); }