/* * Copyright 2014-2016 The OpenSSL Project Authors. All Rights Reserved. * * Licensed under the OpenSSL license (the "License"). You may not use * this file except in compliance with the License. You can obtain a copy * in the file LICENSE in the source distribution or at * https://www.openssl.org/source/license.html */ /*- * Unit test for TLS heartbeats. * * Acts as a regression test against the Heartbleed bug (CVE-2014-0160). * * Author: Mike Bland (mbland@acm.org, http://mike-bland.com/) * Date: 2014-04-12 * License: Creative Commons Attribution 4.0 International (CC By 4.0) * http://creativecommons.org/licenses/by/4.0/deed.en_US * * OUTPUT * ------ * The program returns zero on success. It will print a message with a count * of the number of failed tests and return nonzero if any tests fail. * * It will print the contents of the request and response buffers for each * failing test. In a "fixed" version, all the tests should pass and there * should be no output. * * In a "bleeding" version, you'll see: * * test_dtls1_heartbleed failed: * expected payload len: 0 * received: 1024 * sent 26 characters * "HEARTBLEED " * received 1024 characters * "HEARTBLEED \xde\xad\xbe\xef..." * ** test_dtls1_heartbleed failed ** * * The contents of the returned buffer in the failing test will depend on the * contents of memory on your machine. * * MORE INFORMATION * ---------------- * http://mike-bland.com/2014/04/12/heartbleed.html * http://mike-bland.com/tags/heartbleed.html */ #define OPENSSL_UNIT_TEST #include "../ssl/ssl_locl.h" #include "testutil.h" #include #include #include #include #if !defined(OPENSSL_NO_HEARTBEATS) && !defined(OPENSSL_NO_UNIT_TEST) /* As per https://tools.ietf.org/html/rfc6520#section-4 */ # define MIN_PADDING_SIZE 16 /* Maximum number of payload characters to print as test output */ # define MAX_PRINTABLE_CHARACTERS 1024 typedef struct heartbeat_test_fixture { SSL_CTX *ctx; SSL *s; const char *test_case_name; int (*process_heartbeat) (SSL *s, unsigned char *p, unsigned int length); unsigned char *payload; int sent_payload_len; int expected_return_value; int return_payload_offset; int expected_payload_len; const char *expected_return_payload; } HEARTBEAT_TEST_FIXTURE; static HEARTBEAT_TEST_FIXTURE set_up(const char *const test_case_name, const SSL_METHOD *meth) { HEARTBEAT_TEST_FIXTURE fixture; int setup_ok = 1; memset(&fixture, 0, sizeof(fixture)); fixture.test_case_name = test_case_name; fixture.ctx = SSL_CTX_new(meth); if (!fixture.ctx) { fprintf(stderr, "Failed to allocate SSL_CTX for test: %s\n", test_case_name); setup_ok = 0; goto fail; } fixture.s = SSL_new(fixture.ctx); if (!fixture.s) { fprintf(stderr, "Failed to allocate SSL for test: %s\n", test_case_name); setup_ok = 0; goto fail; } if (!ssl_init_wbio_buffer(fixture.s)) { fprintf(stderr, "Failed to set up wbio buffer for test: %s\n", test_case_name); setup_ok = 0; goto fail; } if (!ssl3_setup_buffers(fixture.s)) { fprintf(stderr, "Failed to setup buffers for test: %s\n", test_case_name); setup_ok = 0; goto fail; } /* * Clear the memory for the return buffer, since this isn't automatically * zeroed in opt mode and will cause spurious test failures that will * change with each execution. */ memset(fixture.s->rlayer.wbuf.buf, 0, fixture.s->rlayer.wbuf.len); fail: if (!setup_ok) { ERR_print_errors_fp(stderr); exit(EXIT_FAILURE); } return fixture; } static HEARTBEAT_TEST_FIXTURE set_up_dtls(const char *const test_case_name) { HEARTBEAT_TEST_FIXTURE fixture = set_up(test_case_name, DTLS_server_method()); fixture.process_heartbeat = dtls1_process_heartbeat; /* * As per dtls1_get_record(), skipping the following from the beginning * of the returned heartbeat message: type-1 byte; version-2 bytes; * sequence number-8 bytes; length-2 bytes And then skipping the 1-byte * type encoded by process_heartbeat for a total of 14 bytes, at which * point we can grab the length and the payload we seek. */ fixture.return_payload_offset = 14; return fixture; } /* Needed by ssl3_write_bytes() */ static int dummy_handshake(SSL *s) { return 1; } static void tear_down(HEARTBEAT_TEST_FIXTURE fixture) { ERR_print_errors_fp(stderr); SSL_free(fixture.s); SSL_CTX_free(fixture.ctx); } static void print_payload(const char *const prefix, const unsigned char *payload, const int n) { const int end = n < MAX_PRINTABLE_CHARACTERS ? n : MAX_PRINTABLE_CHARACTERS; int i = 0; printf("%s %d character%s", prefix, n, n == 1 ? "" : "s"); if (end != n) printf(" (first %d shown)", end); printf("\n \""); for (; i != end; ++i) { const unsigned char c = payload[i]; if (isprint(c)) fputc(c, stdout); else printf("\\x%02x", c); } printf("\"\n"); } static int execute_heartbeat(HEARTBEAT_TEST_FIXTURE fixture) { int result = 0; SSL *s = fixture.s; unsigned char *payload = fixture.payload; unsigned char sent_buf[MAX_PRINTABLE_CHARACTERS + 1]; int return_value; unsigned const char *p; int actual_payload_len; s->rlayer.rrec.data = payload; s->rlayer.rrec.length = strlen((const char *)payload); *payload++ = TLS1_HB_REQUEST; s2n(fixture.sent_payload_len, payload); /* * Make a local copy of the request, since it gets overwritten at some * point */ memcpy(sent_buf, payload, sizeof(sent_buf)); return_value = fixture.process_heartbeat(s, s->rlayer.rrec.data, s->rlayer.rrec.length); if (return_value != fixture.expected_return_value) { printf("%s failed: expected return value %d, received %d\n", fixture.test_case_name, fixture.expected_return_value, return_value); result = 1; } /* * If there is any byte alignment, it will be stored in wbuf.offset. */ p = &(s->rlayer. wbuf.buf[fixture.return_payload_offset + s->rlayer.wbuf.offset]); actual_payload_len = 0; n2s(p, actual_payload_len); if (actual_payload_len != fixture.expected_payload_len) { printf("%s failed:\n expected payload len: %d\n received: %d\n", fixture.test_case_name, fixture.expected_payload_len, actual_payload_len); print_payload("sent", sent_buf, strlen((const char *)sent_buf)); print_payload("received", p, actual_payload_len); result = 1; } else { char *actual_payload = OPENSSL_strndup((const char *)p, actual_payload_len); if (strcmp(actual_payload, fixture.expected_return_payload) != 0) { printf ("%s failed:\n expected payload: \"%s\"\n received: \"%s\"\n", fixture.test_case_name, fixture.expected_return_payload, actual_payload); result = 1; } OPENSSL_free(actual_payload); } if (result != 0) { printf("** %s failed **\n--------\n", fixture.test_case_name); } return result; } static int honest_payload_size(unsigned char payload_buf[]) { /* Omit three-byte pad at the beginning for type and payload length */ return strlen((const char *)&payload_buf[3]) - MIN_PADDING_SIZE; } # define SETUP_HEARTBEAT_TEST_FIXTURE(type)\ SETUP_TEST_FIXTURE(HEARTBEAT_TEST_FIXTURE, set_up_##type) # define EXECUTE_HEARTBEAT_TEST()\ EXECUTE_TEST(execute_heartbeat, tear_down) static int test_dtls1_not_bleeding() { SETUP_HEARTBEAT_TEST_FIXTURE(dtls); /* Three-byte pad at the beginning for type and payload length */ unsigned char payload_buf[MAX_PRINTABLE_CHARACTERS + 4] = " Not bleeding, sixteen spaces of padding" " "; const int payload_buf_len = honest_payload_size(payload_buf); fixture.payload = &payload_buf[0]; fixture.sent_payload_len = payload_buf_len; fixture.expected_return_value = 0; fixture.expected_payload_len = payload_buf_len; fixture.expected_return_payload = "Not bleeding, sixteen spaces of padding"; EXECUTE_HEARTBEAT_TEST(); } static int test_dtls1_not_bleeding_empty_payload() { int payload_buf_len; SETUP_HEARTBEAT_TEST_FIXTURE(dtls); /* * Three-byte pad at the beginning for type and payload length, plus a * NUL at the end */ unsigned char payload_buf[4 + MAX_PRINTABLE_CHARACTERS]; memset(payload_buf, ' ', MIN_PADDING_SIZE + 3); payload_buf[MIN_PADDING_SIZE + 3] = '\0'; payload_buf_len = honest_payload_size(payload_buf); fixture.payload = &payload_buf[0]; fixture.sent_payload_len = payload_buf_len; fixture.expected_return_value = 0; fixture.expected_payload_len = payload_buf_len; fixture.expected_return_payload = ""; EXECUTE_HEARTBEAT_TEST(); } static int test_dtls1_heartbleed() { SETUP_HEARTBEAT_TEST_FIXTURE(dtls); /* Three-byte pad at the beginning for type and payload length */ unsigned char payload_buf[4 + MAX_PRINTABLE_CHARACTERS] = " HEARTBLEED "; fixture.payload = &payload_buf[0]; fixture.sent_payload_len = MAX_PRINTABLE_CHARACTERS; fixture.expected_return_value = 0; fixture.expected_payload_len = 0; fixture.expected_return_payload = ""; EXECUTE_HEARTBEAT_TEST(); } static int test_dtls1_heartbleed_empty_payload() { SETUP_HEARTBEAT_TEST_FIXTURE(dtls); /* * Excluding the NUL at the end, one byte short of type + payload length * + minimum padding */ unsigned char payload_buf[MAX_PRINTABLE_CHARACTERS + 4]; memset(payload_buf, ' ', MIN_PADDING_SIZE + 2); payload_buf[MIN_PADDING_SIZE + 2] = '\0'; fixture.payload = &payload_buf[0]; fixture.sent_payload_len = MAX_PRINTABLE_CHARACTERS; fixture.expected_return_value = 0; fixture.expected_payload_len = 0; fixture.expected_return_payload = ""; EXECUTE_HEARTBEAT_TEST(); } static int test_dtls1_heartbleed_excessive_plaintext_length() { SETUP_HEARTBEAT_TEST_FIXTURE(dtls); /* * Excluding the NUL at the end, one byte in excess of maximum allowed * heartbeat message length */ unsigned char payload_buf[SSL3_RT_MAX_PLAIN_LENGTH + 2]; memset(payload_buf, ' ', sizeof(payload_buf)); payload_buf[sizeof(payload_buf) - 1] = '\0'; fixture.payload = &payload_buf[0]; fixture.sent_payload_len = honest_payload_size(payload_buf); fixture.expected_return_value = 0; fixture.expected_payload_len = 0; fixture.expected_return_payload = ""; EXECUTE_HEARTBEAT_TEST(); } # undef EXECUTE_HEARTBEAT_TEST # undef SETUP_HEARTBEAT_TEST_FIXTURE int main(int argc, char *argv[]) { int result = 0; ADD_TEST(test_dtls1_not_bleeding); ADD_TEST(test_dtls1_not_bleeding_empty_payload); ADD_TEST(test_dtls1_heartbleed); ADD_TEST(test_dtls1_heartbleed_empty_payload); ADD_TEST(test_dtls1_heartbleed_excessive_plaintext_length); result = run_tests(argv[0]); ERR_print_errors_fp(stderr); return result; } #else /* OPENSSL_NO_HEARTBEATS */ int main(int argc, char *argv[]) { return EXIT_SUCCESS; } #endif /* OPENSSL_NO_HEARTBEATS */